Catalytic conversion of formic acid to methanol with Cu and Al under hydrothermal conditions

Hansong Yao; Xu Zeng; Min Cheng; Jun Yun; Zhenzi Jing; Fangming Jin

Catalytic conversion of formic acid to methanol with Cu and Al under hydrothermal conditions

Hansong Yao, Xu Zeng, Min Cheng, Jun Yun, Zhenzi Jing, Fangming Jin

ENV - Environmental Studies for Advanced Society

Research output: Contribution to journal › Article › peer-review

8 Citations (Scopus)

Abstract

Catalytic conversion of formic acid into methanol was investigated with Cu as a catalyst and Al as a reductant under hydrothermal conditions. It was found that formic acid can be converted into methanol by such means. The highest yield of methanol (30.4%) was attained with a temperature of 300 °C and a reaction time of 9 h. The AlO(OH) formed from Al oxidation may also play a catalytic role in the formation of methanol. This process may provide a promising solution to producing methanol from carbohydrate biomass combined with the process of converting the carbohydrate into formic acid, which is expected to emit no CO ₂.

Original language	English
Pages (from-to)	972-983
Number of pages	12
Journal	BioResources
Volume	7
Issue number	1
Publication status	Published - 2012 Feb 1

Keywords

Biomass utilization
Catalytic reduction
Hydrothermal conditions
Methanol

ASJC Scopus subject areas

Environmental Engineering
Bioengineering
Waste Management and Disposal

Cite this

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abstract = "Catalytic conversion of formic acid into methanol was investigated with Cu as a catalyst and Al as a reductant under hydrothermal conditions. It was found that formic acid can be converted into methanol by such means. The highest yield of methanol (30.4%) was attained with a temperature of 300 °C and a reaction time of 9 h. The AlO(OH) formed from Al oxidation may also play a catalytic role in the formation of methanol. This process may provide a promising solution to producing methanol from carbohydrate biomass combined with the process of converting the carbohydrate into formic acid, which is expected to emit no CO 2.",

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T1 - Catalytic conversion of formic acid to methanol with Cu and Al under hydrothermal conditions

AU - Yao, Hansong

AU - Zeng, Xu

AU - Cheng, Min

AU - Yun, Jun

AU - Jing, Zhenzi

AU - Jin, Fangming

PY - 2012/2/1

Y1 - 2012/2/1

N2 - Catalytic conversion of formic acid into methanol was investigated with Cu as a catalyst and Al as a reductant under hydrothermal conditions. It was found that formic acid can be converted into methanol by such means. The highest yield of methanol (30.4%) was attained with a temperature of 300 °C and a reaction time of 9 h. The AlO(OH) formed from Al oxidation may also play a catalytic role in the formation of methanol. This process may provide a promising solution to producing methanol from carbohydrate biomass combined with the process of converting the carbohydrate into formic acid, which is expected to emit no CO 2.

AB - Catalytic conversion of formic acid into methanol was investigated with Cu as a catalyst and Al as a reductant under hydrothermal conditions. It was found that formic acid can be converted into methanol by such means. The highest yield of methanol (30.4%) was attained with a temperature of 300 °C and a reaction time of 9 h. The AlO(OH) formed from Al oxidation may also play a catalytic role in the formation of methanol. This process may provide a promising solution to producing methanol from carbohydrate biomass combined with the process of converting the carbohydrate into formic acid, which is expected to emit no CO 2.

KW - Biomass utilization

KW - Catalytic reduction

KW - Hydrothermal conditions

KW - Methanol

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Catalytic conversion of formic acid to methanol with Cu and Al under hydrothermal conditions

Abstract

Keywords

ASJC Scopus subject areas

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