Interest in hydrogen as a possible energy vector is powered by the depletion of fossil fuel feedstocks as well as concerns over global warming, which brings new environmental legislations on the emission of greenhouse gases into the atmosphere. At this point, the future perspective of a hydrogen economy has triggered many researchers to develop and optimize a series of new technologies which differ from conventional industrial processes (like SMR, ATR, POX, and H 2 O-electrolysis) in their orientation toward the minimization of emission of greenhouse gases (on-site CO 2 capture), utilization of renewable feedstock (bio-alcohols, bio-gases, wood, and algae), or renewable energy sources (wind, sunlight, or tides). This chapter gathers information on the most relevant technologies for hydrogen production, including discussions on existing conventional reforming processes, as well as developments in advanced and more environmentally benign methods, like chemical-looping.
Vozniuk O., Tanchoux N., Millet J.-M., Albonetti S., Di Renzo F., Cavani F. (2019). Spinel Mixed Oxides for Chemical-Loop Reforming: From Solid State to Potential Application. Amsterdam, Netherlands : Elsevier Inc. [10.1016/B978-0-444-64127-4.00014-8].
Spinel Mixed Oxides for Chemical-Loop Reforming: From Solid State to Potential Application
Vozniuk O.;Albonetti S.;Cavani F.
2019
Abstract
Interest in hydrogen as a possible energy vector is powered by the depletion of fossil fuel feedstocks as well as concerns over global warming, which brings new environmental legislations on the emission of greenhouse gases into the atmosphere. At this point, the future perspective of a hydrogen economy has triggered many researchers to develop and optimize a series of new technologies which differ from conventional industrial processes (like SMR, ATR, POX, and H 2 O-electrolysis) in their orientation toward the minimization of emission of greenhouse gases (on-site CO 2 capture), utilization of renewable feedstock (bio-alcohols, bio-gases, wood, and algae), or renewable energy sources (wind, sunlight, or tides). This chapter gathers information on the most relevant technologies for hydrogen production, including discussions on existing conventional reforming processes, as well as developments in advanced and more environmentally benign methods, like chemical-looping.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
