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Novel chemical looping oxidation of biomass-derived carbohydrates to super-high-yield formic acid using heteropolyacids as oxygen carrier

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  • He, Zhuosen
  • Hou, Yucui
  • Li, He
  • Wei, Jian
  • Ren, Shuhang
  • Wu, Weize

Abstract

In recent years, formic acid (FA) shows great potential in fuel cells and hydrogen storage. For FA production from renewable resources, catalytic aerobic oxidation of biomass to FA has been reported. However, the yield of by-product CO2 is fairly high, limiting the FA selectivity and causing greenhouse gas emission. Herein, a novel chemical looping oxidation of biomass-derived carbohydrates to FA was first proposed. A heteropolyacid H8PV5Mo7O40 (HPA-5) was selected as an excellent oxygen carrier. Oxidation of carbohydrates to FA and re-oxidation of reduced HPA-5 (HPA-5red) by O2 were separately performed, by which the FA yield from glucose achieved 95.4%. The extremely high yield of FA is attributed to two reasons. On one hand, the chemical looping process avoids over-oxidation caused by the hydroxyl radicals formed in the re-oxidation of HPA-5red. On the other hand, abundant HPA-5 promotes the glucose oxidation to FA, suppressing the acid-catalyzed decomposition and the oxidation toward saccharic acids. Besides, HPA-5red can be completely re-oxidized by O2 and the chemical looping oxidation has stably performed well in five chemical cycles. This oxidation strategy also shows outstanding FA yields from xylan, cellulose and raw biomass.

Suggested Citation

  • He, Zhuosen & Hou, Yucui & Li, He & Wei, Jian & Ren, Shuhang & Wu, Weize, 2023. "Novel chemical looping oxidation of biomass-derived carbohydrates to super-high-yield formic acid using heteropolyacids as oxygen carrier," Renewable Energy, Elsevier, vol. 207(C), pages 461-470.
  • Handle: RePEc:eee:renene:v:207:y:2023:i:c:p:461-470
    DOI: 10.1016/j.renene.2023.03.025
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    References listed on IDEAS

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    1. Caglar, Aykut & Cogenli, Mehmet Selim & Yurtcan, Ayşe Bayrakçeken & Kivrak, Hilal, 2020. "Effective carbon nanotube supported metal (M=Au, Ag, Co, Mn, Ni, V, Zn) core Pd shell bimetallic anode catalysts for formic acid fuel cells," Renewable Energy, Elsevier, vol. 150(C), pages 78-90.
    2. Patel, Jay & Patel, Anjali, 2022. "Solvent free hydrogenation of levulinic acid over in-situ generated Ni(0) stabilized by supported phosphomolybdic acid using formic acid as an internal hydrogen source," Renewable Energy, Elsevier, vol. 201(P2), pages 190-201.
    3. Sert, Murat & Arslanoğlu, Alparslan & Ballice, Levent, 2018. "Conversion of sunflower stalk based cellulose to the valuable products using choline chloride based deep eutectic solvents," Renewable Energy, Elsevier, vol. 118(C), pages 993-1000.
    4. Shen, Feng & Li, Ye & Qin, Xiaoya & Guo, Haixin & Li, Jialu & Yang, Jirui & Ding, Yongzhen, 2022. "Selective oxidation of cellulose into formic acid over heteropolyacid-based temperature responsive catalysts," Renewable Energy, Elsevier, vol. 185(C), pages 139-146.
    5. Jinling Wang & Xingchao Dai & Hualin Wang & Honglai Liu & Jabor Rabeah & Angelika Brückner & Feng Shi & Ming Gong & Xuejing Yang, 2021. "Dihydroxyacetone valorization with high atom efficiency via controlling radical oxidation pathways over natural mineral-inspired catalyst," Nature Communications, Nature, vol. 12(1), pages 1-11, December.
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    1. He, Zhuosen & Hou, Yucui & Li, He & Wang, Yupeng & Ren, Shuhang & Wu, Weize, 2023. "Novel insights into CO2 inhibition with additives in catalytic aerobic oxidation of biomass-derived carbohydrates to formic acid," Renewable Energy, Elsevier, vol. 211(C), pages 403-411.
    2. Chai, Yu & Tian, Xin-Yu & Zheng, Xiao-Ping & Du, Ya-Peng & Zhang, Yu-Cang & Zheng, Yan-Zhen, 2024. "An effective approach for chitosan conversion to 5-hydroxymethylfurfural catalyzed by bio-based organic acid with ionic liquids additive," Renewable Energy, Elsevier, vol. 221(C).

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