TY - JOUR
T1 - Green hydrogen-based E-fuels (E-methane, E-methanol, E-ammonia) to support clean energy transition
T2 - A literature review
AU - Nemmour, Amira
AU - Inayat, Abrar
AU - Janajreh, Isam
AU - Ghenai, Chaouki
N1 - Publisher Copyright:
© 2023 Hydrogen Energy Publications LLC
PY - 2023/9/1
Y1 - 2023/9/1
N2 - Renewable power-to-fuel (PtF) is a key technology for the transition towards fossil-free energy systems. The production of carbon neutral synthetic fuels is primarily driven by the need to decouple the energy sector from fossil fuels dependance which are the main source of environmental issues. Hydrogen (H2) produced from water electrolysis powered by renewable electricity and direct carbon dioxide (CO2) captured from the flue gas generated by power plants, industry, transportation, and biogas production from anaerobic digestion, are used to convert electricity into carbon-neutral synthetic fuels. These fuels function as effective energy carriers that can be stored, transported, and used in other energy sectors (transport and industry). In addition, the PtF concept is an energy transformation that is capable of providing services for the balancing of the electricity grid thanks to its adaptable operation and long-term storage capacities for renewable energy surplus. As a consequence, it helps to potentially decarbonize the energy sector by reducing the carbon footprint and GHG emissions. This paper gives an overview on recent advances of renewable PtF technology for the e-production of three main hydrogen-based synthetic fuels that could substitute fossil fuels such as power-to-methane (PtCH4), power-to-methanol (PtCH3OH) and power-to-ammonia (PtNH3). The first objective is to thoroughly define in a clear manner the framework which includes the PtF technologies. Attention is given to green H2 production by water electrolysis, carbon capture & storage (CCS), CO2 hydrogenation, Sabatier, and Haber Bosch processes. The second objective is to gather and classify some existing projects which deal with this technology depending on the e-fuel produced (energy input, conversion process, efficiency, fuel produced, and application). Furthermore, the challenges and future prospects of achieving sustainable large-scale PtF applications are discussed.
AB - Renewable power-to-fuel (PtF) is a key technology for the transition towards fossil-free energy systems. The production of carbon neutral synthetic fuels is primarily driven by the need to decouple the energy sector from fossil fuels dependance which are the main source of environmental issues. Hydrogen (H2) produced from water electrolysis powered by renewable electricity and direct carbon dioxide (CO2) captured from the flue gas generated by power plants, industry, transportation, and biogas production from anaerobic digestion, are used to convert electricity into carbon-neutral synthetic fuels. These fuels function as effective energy carriers that can be stored, transported, and used in other energy sectors (transport and industry). In addition, the PtF concept is an energy transformation that is capable of providing services for the balancing of the electricity grid thanks to its adaptable operation and long-term storage capacities for renewable energy surplus. As a consequence, it helps to potentially decarbonize the energy sector by reducing the carbon footprint and GHG emissions. This paper gives an overview on recent advances of renewable PtF technology for the e-production of three main hydrogen-based synthetic fuels that could substitute fossil fuels such as power-to-methane (PtCH4), power-to-methanol (PtCH3OH) and power-to-ammonia (PtNH3). The first objective is to thoroughly define in a clear manner the framework which includes the PtF technologies. Attention is given to green H2 production by water electrolysis, carbon capture & storage (CCS), CO2 hydrogenation, Sabatier, and Haber Bosch processes. The second objective is to gather and classify some existing projects which deal with this technology depending on the e-fuel produced (energy input, conversion process, efficiency, fuel produced, and application). Furthermore, the challenges and future prospects of achieving sustainable large-scale PtF applications are discussed.
KW - Carbon dioxide recycling
KW - E-Fuels
KW - Green hydrogen
KW - PtCHOH
KW - PtCH
KW - PtNH
KW - Synthetic fuels
UR - http://www.scopus.com/inward/record.url?scp=85153928694&partnerID=8YFLogxK
U2 - 10.1016/j.ijhydene.2023.03.240
DO - 10.1016/j.ijhydene.2023.03.240
M3 - Review article
AN - SCOPUS:85153928694
SN - 0360-3199
VL - 48
SP - 29011
EP - 29033
JO - International Journal of Hydrogen Energy
JF - International Journal of Hydrogen Energy
IS - 75
ER -