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Literature DB >> 26821793

NaHCO3-enhanced hydrogen production from water with Fe and in situ highly efficient and autocatalytic NaHCO3 reduction into formic acid.

Jia Duo¹, Fangming Jin², Yuanqing Wang³, Heng Zhong⁴, Lingyun Lyu¹, Guodong Yao¹, Zhibao Huo¹.

Abstract

We report a highly efficient water splitting for CO2 reduction into formic acid with a commercially available metal of Fe powder without adding any other catalyst. An excellent formic acid yield of more than 90% was attained.

Entities: Chemical

Year: 2016 PMID： 26821793 DOI： 10.1039/c5cc09611a

Source DB: PubMed Journal: Chem Commun (Camb) ISSN： 1359-7345 Impact factor: 6.222

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Cited

3 in total

1. Pathways and Kinetics for Autocatalytic Reduction of CO₂ into Formic Acid with Fe under Hydrothermal Conditions.

Authors: Binbin Jin; Ligang Luo; Longfei Xie
Journal: ACS Omega Date: 2021-04-23

2. Hydrothermal CO₂ Reduction by Glucose as Reducing Agent and Metals and Metal Oxides as Catalysts.

Authors: Maira I Chinchilla; Fidel A Mato; Ángel Martín; María D Bermejo
Journal: Molecules Date: 2022-03-02 Impact factor: 4.411

3. Role of geochemical protoenzymes (geozymes) in primordial metabolism: specific abiotic hydride transfer by metals to the biological redox cofactor NAD^.

Authors: Delfina P Henriques Pereira; Jana Leethaus; Tugce Beyazay; Andrey do Nascimento Vieira; Karl Kleinermanns; Harun Tüysüz; William F Martin; Martina Preiner
Journal: FEBS J Date: 2022-01-03 Impact factor: 5.622

3 in total

NaHCO3-enhanced hydrogen production from water with Fe and in situ highly efficient and autocatalytic NaHCO3 reduction into formic acid.

1. Pathways and Kinetics for Autocatalytic Reduction of CO2 into Formic Acid with Fe under Hydrothermal Conditions.

2. Hydrothermal CO2 Reduction by Glucose as Reducing Agent and Metals and Metal Oxides as Catalysts.

3. Role of geochemical protoenzymes (geozymes) in primordial metabolism: specific abiotic hydride transfer by metals to the biological redox cofactor NAD.

1. Pathways and Kinetics for Autocatalytic Reduction of CO₂ into Formic Acid with Fe under Hydrothermal Conditions.

2. Hydrothermal CO₂ Reduction by Glucose as Reducing Agent and Metals and Metal Oxides as Catalysts.

3. Role of geochemical protoenzymes (geozymes) in primordial metabolism: specific abiotic hydride transfer by metals to the biological redox cofactor NAD^.