RFCS-2026-02-AMRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-02-PDPRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-02-RPJRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-01-AMRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-01-RPJRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-01-PDPRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-02-PDPRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-02-AMRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-02-RPJRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-01-PDPRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-01-RPJRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-01-AMRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-02-RPJRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-01-PDPRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-01-AMRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-01-RPJRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-02-PDPRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-02-AMRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-02-PDPRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-02-AMRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-02-RPJRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-01-PDPRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-01-AMRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-01-RPJRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-02-PDPRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-02-AMRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-02-RPJRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-01-AMRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-01-PDPRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-01-RPJRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-02-PDPRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-02-AMRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-02-RPJRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-01-PDPRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-01-AMRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-01-RPJRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-01-RPJRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-01-PDPRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-02-PDPRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-02-AMRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-02-RPJRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-01-AMRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-02-PDPRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-02-AMRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-02-RPJRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-01-PDPRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-01-AMRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-01-RPJRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-02-AMRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-02-PDPRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-02-RPJRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-01-AMRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-01-PDPRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-01-RPJRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-02-AMRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-02-PDPRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-02-RPJRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-01-PDPRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-01-AMRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-01-RPJRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-02-PDPRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-02-AMRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-02-RPJRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-01-PDPRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-01-RPJRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-01-AMRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-02-PDPRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-02-RPJRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-02-AMRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-01-PDPRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-01-RPJRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-01-AMRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-01-AMRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-01-PDPRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-01-RPJRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-02-PDPRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-02-AMRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-02-RPJRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-02-PDPRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-02-AMRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-02-RPJRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-01-AMRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-01-PDPRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-01-RPJRFCS-2026(art.4) carbon dioxide capture(art.4) carbon dioxide storage(art.4) carbon dioxide use(art.4) climate impact of closing mines(art.4) closing coal mines(art.4) coal infrastructure(art.4) environmental impact of mining wastes(art.4) geothermal energy(art.4) mining wastes(art.4) non-energetic uses of mining wastes(art.4) production of raw materials from mining wastes(art.5) Health in coal mines(art.5) Safety in coal mines(art.5) closure of mines(art.5) disseas related to coal mines(art.5) health of people in coal regions(art.5) protective measures(art.5) social impact of closure mines(art.5) working conditions in coal mines(art.6) atmosphere pollution(art.6) avoiding and minimising greenhouse gas emissions(art.6) avoiding and minimising methane(art.6) capturing greenhouse gas emissions(art.6) capturing methane(art.6) coal deposits(art.6) coal wastes(art.6) desulphurisation products from coal mines(art.6) environmental impact(art.6) environmental pollution(art.6) land pollution(art.6) managing and reusing fly ash(art.6) managing and reusing mining waste(art.6) methane leakage(art.6) minimising greenhouse gas emissions(art.6) minimising methane(art.6) protecting surface infrastructure against the effects of ground movements(art.6) protecting surface infrastructure against the effects of subsidence(art.6) protecting water tables(art.6) purifying mine drainage water(art.6) refurbishing waste heaps from coal production(art.6) restoring the environment of installations using coal(art.6) soils pollution(art.6) using industrially residues from coal consumption(art.6) using industrially residues from coal production(art.6) water pollutionResearch Objective Art.4 - Supporting the just transition of the coal sector and regionsResearch Objective Art.5 - Improving health and safetyResearch Objective Art.6 - Minimising the environmental impacts of coal mines in transition
RFCS-2026-02-PDPRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications
RFCS-2026-02-RPJRFCS-2026(art.10) assembled structures(art.10) circular economy(art.10) design of steel grades(art.10) elimination of waste gases(art.10) emissions(art.10) life cycle assessment(art.10) pollution control(art.10) protection of the environment(art.10) raw materials(art.10) recovery secondary raw materials(art.10) recycling obsolete steel(art.10) recycling steel by-products(art.10) slags(art.10) steel recovery(art.10) steel recycling(art.10) steel reuse(art.10) steel scrap(art.10) treatment of waste(art.10) utilisation of process gases(art.10) waste(art.10) water management(art.10a) developing competencies(art.10a) disseminating competencies(art.10a) ergonomics(art.10a) health conditions(art.10a) lifelong learning(art.10a) safety conditions(art.10a) working conditions(art.8) application of big data(art.8) artificial intelligence(art.8) automation(art.8) carbon avoidance(art.8) carbon usage(art.8) casting operations(art.8) clean hydrogen economy(art.8) coating operations(art.8) control(art.8) digitalisation(art.8) energy efficiency of steel production(art.8) energy management solutions(art.8) finishing operations(art.8) hybrid heating techniques(art.8) iron- and steel-making processes(art.8) maintenance of steel production tools(art.8) metallurgy(art.8) modelling(art.8) near-zero-carbon steel production(art.8) prevention of energy losses(art.8) process chain optimisation(art.8) recovery of waste heat(art.8) recycled scrap melting(art.8) reduction and pre-reduction of iron-ore(art.8) reliability of steel production tools(art.8) rolling operations(art.8) secondary metallurgy(art.8) steel process(art.8) steel-making(art.8) steel-making operations(art.8) steel-making processes(art.8) zero-carbon energy production(art.9) corrosion resistance(art.9) eco-design methods(art.9) heat resistance(art.9) lightweight design(art.9) material properties(art.9) mechanical and physical properties(art.9) mechanical fatigue(art.9) mobility applications(art.9) predictive simulation models(art.9) predictive simulation models on mechanical properties(art.9) predictive simulation models on microstructures(art.9) predictive simulation models on production processes(art.9) retrofitting(art.9) safety solutions(art.9) standardisation(art.9) standardisation of testing and evaluation methods(art.9) steel grades(art.9) steel properties(art.9) steel resistance(art.9) sustainability(art.9) thermal fatigueResearch Objective Art.10 - Conservation of resources, protection of the environment and circular economyResearch Objective Art.10a - Management of work force and working conditionsResearch Objective Art.8 - New, sustainable and low-carbon steelmaking and finishing processesResearch Objective Art.9 - Advanced steel grades and applications