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Progress in in-situ CO2-sorption for enhanced hydrogen production

Vineet Sikarwar (UGent) , Christoph Pfeifer, Frederik Ronsse (UGent) , Michael Pohořelý, Erik Meers (UGent) , Ajay Kumar Kaviti and Michal Jeremiáš
(2022) PROGRESS IN ENERGY AND COMBUSTION SCIENCE. 91.
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Abstract
Deployment of fossil fuels to quench the energy demand of the world's rising population results in elevated levels of greenhouse gas (GHG) emissions, especially CO2, which in turn is responsible for undesirable climate change. This necessitates a shift toward cleaner energy resources such as hydrogen. Enhanced hydrogen production via steam reforming of diverse fuels (methane, biomass, organic wastes, etc.) with in-situ CO2-sorption seems to be a promising alternative. Leading-edge, innovative and eco-friendly pathways coupled with high process efficiencies are needed for the development and growth of this technology. This review article evaluates the fundamental concepts such as criteria for CO2 uptake, mechanisms, thermodynamics and kinetics of the water gas shift reaction along with different modeling methods for sorption enhanced processes. Moreover, research works carried out worldwide at lab-scale coupled with process development and demonstration units are discussed as a means to encourage this pathway for H-2 generation. Furthermore, light is shed on techno-economics as an approach to improve the viability and sustainability of the proposed technology. This paper analyzes different dimensions of the CO2-sorption enhanced process to promote it as a potentially carbon-neutral and ecofriendly pathway for hydrogen production.
Keywords
Economics, Hydrogen, Modeling, Solid sorbents, CO2 capture, WATER-GAS-SHIFT, CARBON-DIOXIDE CAPTURE, FLUIDIZED-BED REACTOR, ARTIFICIAL NEURAL-NETWORKS, TEMPERATURE CO2 SORPTION, STEAM REFORMING PROCESS, ALKALI-METAL NITRATE, RANDOM PORE MODEL, THERMODYNAMIC ANALYSIS, H-2 PRODUCTION

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MLA
Sikarwar, Vineet, et al. “Progress in In-Situ CO2-Sorption for Enhanced Hydrogen Production.” PROGRESS IN ENERGY AND COMBUSTION SCIENCE, vol. 91, 2022, doi:10.1016/j.pecs.2022.101008.
APA
Sikarwar, V., Pfeifer, C., Ronsse, F., Pohořelý, M., Meers, E., Kaviti, A. K., & Jeremiáš, M. (2022). Progress in in-situ CO2-sorption for enhanced hydrogen production. PROGRESS IN ENERGY AND COMBUSTION SCIENCE, 91. https://doi.org/10.1016/j.pecs.2022.101008
Chicago author-date
Sikarwar, Vineet, Christoph Pfeifer, Frederik Ronsse, Michael Pohořelý, Erik Meers, Ajay Kumar Kaviti, and Michal Jeremiáš. 2022. “Progress in In-Situ CO2-Sorption for Enhanced Hydrogen Production.” PROGRESS IN ENERGY AND COMBUSTION SCIENCE 91. https://doi.org/10.1016/j.pecs.2022.101008.
Chicago author-date (all authors)
Sikarwar, Vineet, Christoph Pfeifer, Frederik Ronsse, Michael Pohořelý, Erik Meers, Ajay Kumar Kaviti, and Michal Jeremiáš. 2022. “Progress in In-Situ CO2-Sorption for Enhanced Hydrogen Production.” PROGRESS IN ENERGY AND COMBUSTION SCIENCE 91. doi:10.1016/j.pecs.2022.101008.
Vancouver
1.
Sikarwar V, Pfeifer C, Ronsse F, Pohořelý M, Meers E, Kaviti AK, et al. Progress in in-situ CO2-sorption for enhanced hydrogen production. PROGRESS IN ENERGY AND COMBUSTION SCIENCE. 2022;91.
IEEE
[1]
V. Sikarwar et al., “Progress in in-situ CO2-sorption for enhanced hydrogen production,” PROGRESS IN ENERGY AND COMBUSTION SCIENCE, vol. 91, 2022.
@article{8751451,
  abstract     = {{Deployment of fossil fuels to quench the energy demand of the world's rising population results in elevated levels of greenhouse gas (GHG) emissions, especially CO2, which in turn is responsible for undesirable climate change. This necessitates a shift toward cleaner energy resources such as hydrogen. Enhanced hydrogen production via steam reforming of diverse fuels (methane, biomass, organic wastes, etc.) with in-situ CO2-sorption seems to be a promising alternative. Leading-edge, innovative and eco-friendly pathways coupled with high process efficiencies are needed for the development and growth of this technology. This review article evaluates the fundamental concepts such as criteria for CO2 uptake, mechanisms, thermodynamics and kinetics of the water gas shift reaction along with different modeling methods for sorption enhanced processes. Moreover, research works carried out worldwide at lab-scale coupled with process development and demonstration units are discussed as a means to encourage this pathway for H-2 generation. Furthermore, light is shed on techno-economics as an approach to improve the viability and sustainability of the proposed technology. This paper analyzes different dimensions of the CO2-sorption enhanced process to promote it as a potentially carbon-neutral and ecofriendly pathway for hydrogen production.}},
  articleno    = {{101008}},
  author       = {{Sikarwar, Vineet and Pfeifer, Christoph and Ronsse, Frederik and Pohořelý, Michael and Meers, Erik and Kaviti, Ajay Kumar and Jeremiáš, Michal}},
  issn         = {{0360-1285}},
  journal      = {{PROGRESS IN ENERGY AND COMBUSTION SCIENCE}},
  keywords     = {{Economics,Hydrogen,Modeling,Solid sorbents,CO2 capture,WATER-GAS-SHIFT,CARBON-DIOXIDE CAPTURE,FLUIDIZED-BED REACTOR,ARTIFICIAL NEURAL-NETWORKS,TEMPERATURE CO2 SORPTION,STEAM REFORMING PROCESS,ALKALI-METAL NITRATE,RANDOM PORE MODEL,THERMODYNAMIC ANALYSIS,H-2 PRODUCTION}},
  language     = {{eng}},
  pages        = {{34}},
  title        = {{Progress in in-situ CO2-sorption for enhanced hydrogen production}},
  url          = {{http://dx.doi.org/10.1016/j.pecs.2022.101008}},
  volume       = {{91}},
  year         = {{2022}},
}
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