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Carbohydrate-to-hydrogen production technologies: A mini-review

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  • Sharma, Kamlesh

Abstract

Hydrogen is a promising future with high-energy utilization efficiency and a clean energy carrier featuring lower emissions of pollutants as compared to the liquid fuels used in internal combustion engines. Hydrogen fuel production from renewable biomass carbohydrates has a better future perspective as it achieves zero CO2 emissions lifecycle and hence will reduce global warming, acid rain and improve rural economy. Herein, we present H2 production from biomass carbohydrates by using different types of catalysis such chemical catalysis, biocatalysis, and their combinations. The chemical catalysis includes aqueous phase reforming, pyrolysis, gasification, and gasification in supercritical water. The biocatalysis includes electrohydrogenesis, anaerobic fermentation, photo-fermentation, cell-free synthetic pathway biotransformation (cell-free SyPaB). Since, energy efficiency or hydrogen yield is the most critical economic factor for H2 production, cell-free SyPaB which can produce 12H2 / glucose equivalent appears to be a potential solution for H2 production. In addition, the pathway design of cell-free SyPaB has several advantages such as use of availability of stable enzymes and coenzymes building blocks, less expensive bioreactors, modest reaction conditions, acceptable reaction rates, metabolic load balancing, in-situ monitoring, absence of cell membrane, real-time control, and reduced toxicity effects. Along with all these advantages, cell-free SyPaB addresses few more challenges associated with costly infrastructure, distribution, storage and safety.

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  • Sharma, Kamlesh, 2019. "Carbohydrate-to-hydrogen production technologies: A mini-review," Renewable and Sustainable Energy Reviews, Elsevier, vol. 105(C), pages 138-143.
    • Handle: RePEc:eee:rensus:v:105:y:2019:i:c:p:138-143
    DOI: 10.1016/j.rser.2019.01.054
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    1. R. D. Cortright & R. R. Davda & J. A. Dumesic, 2002. "Hydrogen from catalytic reforming of biomass-derived hydrocarbons in liquid water," Nature, Nature, vol. 418(6901), pages 964-967, August.
    2. Kumar, G. & Bakonyi, P. & Periyasamy, S. & Kim, S.H. & Nemestóthy, N. & Bélafi-Bakó, K., 2015. "Lignocellulose biohydrogen: Practical challenges and recent progress," Renewable and Sustainable Energy Reviews, Elsevier, vol. 44(C), pages 728-737.
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    2. Xu, Chunping & Paone, Emilia & Rodríguez-Padrón, Daily & Luque, Rafael & Mauriello, Francesco, 2020. "Reductive catalytic routes towards sustainable production of hydrogen, fuels and chemicals from biomass derived polyols," Renewable and Sustainable Energy Reviews, Elsevier, vol. 127(C).
    3. Sittijunda, Sureewan & Reungsang, Alissara, 2020. "Valorization of crude glycerol into hydrogen, 1,3-propanediol, and ethanol in an up-flow anaerobic sludge blanket (UASB) reactor under thermophilic conditions," Renewable Energy, Elsevier, vol. 161(C), pages 361-372.
    4. Raluca-Andreea Felseghi & Elena Carcadea & Maria Simona Raboaca & Cătălin Nicolae TRUFIN & Constantin Filote, 2019. "Hydrogen Fuel Cell Technology for the Sustainable Future of Stationary Applications," Energies, MDPI, vol. 12(23), pages 1-28, December.
    5. Loganath, Radhakrishnan & Senophiyah-Mary, J., 2020. "Critical review on the necessity of bioelectricity generation from slaughterhouse industry waste and wastewater using different anaerobic digestion reactors," Renewable and Sustainable Energy Reviews, Elsevier, vol. 134(C).
    6. Umair Yaqub Qazi, 2022. "Future of Hydrogen as an Alternative Fuel for Next-Generation Industrial Applications; Challenges and Expected Opportunities," Energies, MDPI, vol. 15(13), pages 1-40, June.

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