Hydrogen production from the air

Jining Guo; Yuecheng Zhang; Ali Zavabeti; Kaifei Chen; Yalou Guo; Guoping Hu; Xiaolei Fan; Gang Kevin Li

doi:10.1038/s41467-022-32652-y

Hydrogen production from the air

Jining Guo, Yuecheng Zhang, Ali Zavabeti, Kaifei Chen, Yalou Guo, Guoping Hu, Xiaolei Fan, Gang Kevin Li

Chemical & Biological Engineering

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

134 Citations (Scopus)

Abstract

Green hydrogen produced by water splitting using renewable energy is the most promising energy carrier of the low-carbon economy. However, the geographic mismatch between renewables distribution and freshwater availability poses a significant challenge to its production. Here, we demonstrate a method of direct hydrogen production from the air, namely, in situ capture of freshwater from the atmosphere using hygroscopic electrolyte and electrolysis powered by solar or wind with a current density up to 574 mA cm⁻². A prototype of such has been established and operated for 12 consecutive days with a stable performance at a Faradaic efficiency around 95%. This so-called direct air electrolysis (DAE) module can work under a bone-dry environment with a relative humidity of 4%, overcoming water supply issues and producing green hydrogen sustainably with minimal impact to the environment. The DAE modules can be easily scaled to provide hydrogen to remote, (semi-) arid, and scattered areas.

Original language	English
Article number	5046
Number of pages	9
Journal	Nature Communications
Volume	13
Issue number	1
DOIs	https://doi.org/10.1038/s41467-022-32652-y
Publication status	Published - 6 Sept 2022

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 6 Clean Water and Sanitation
SDG 7 Affordable and Clean Energy
SDG 8 Decent Work and Economic Growth
SDG 12 Responsible Consumption and Production

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10.1038/s41467-022-32652-y

Cite this

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title = "Hydrogen production from the air",

abstract = "Green hydrogen produced by water splitting using renewable energy is the most promising energy carrier of the low-carbon economy. However, the geographic mismatch between renewables distribution and freshwater availability poses a significant challenge to its production. Here, we demonstrate a method of direct hydrogen production from the air, namely, in situ capture of freshwater from the atmosphere using hygroscopic electrolyte and electrolysis powered by solar or wind with a current density up to 574 mA cm−2. A prototype of such has been established and operated for 12 consecutive days with a stable performance at a Faradaic efficiency around 95\%. This so-called direct air electrolysis (DAE) module can work under a bone-dry environment with a relative humidity of 4\%, overcoming water supply issues and producing green hydrogen sustainably with minimal impact to the environment. The DAE modules can be easily scaled to provide hydrogen to remote, (semi-) arid, and scattered areas.",

author = "Jining Guo and Yuecheng Zhang and Ali Zavabeti and Kaifei Chen and Yalou Guo and Guoping Hu and Xiaolei Fan and Li, \{Gang Kevin\}",

note = "Funding Information: J. G. is grateful for the Melbourne-Manchester Graduate Research scholarship. Funding Information: J. G. is grateful for the Melbourne-Manchester Graduate Research scholarship. This work was performed in part at the Materials Characterization and Fabrication Platform (MCFP) at the University of Melbourne and the Victorian Node of the Australian National Fabrication Facility (ANFF). Publisher Copyright: {\textcopyright} 2022, The Author(s).",

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AU - Guo, Jining

AU - Zhang, Yuecheng

AU - Zavabeti, Ali

AU - Chen, Kaifei

AU - Guo, Yalou

AU - Hu, Guoping

AU - Fan, Xiaolei

AU - Li, Gang Kevin

N1 - Funding Information: J. G. is grateful for the Melbourne-Manchester Graduate Research scholarship. Funding Information: J. G. is grateful for the Melbourne-Manchester Graduate Research scholarship. This work was performed in part at the Materials Characterization and Fabrication Platform (MCFP) at the University of Melbourne and the Victorian Node of the Australian National Fabrication Facility (ANFF). Publisher Copyright: © 2022, The Author(s).

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Y1 - 2022/9/6

N2 - Green hydrogen produced by water splitting using renewable energy is the most promising energy carrier of the low-carbon economy. However, the geographic mismatch between renewables distribution and freshwater availability poses a significant challenge to its production. Here, we demonstrate a method of direct hydrogen production from the air, namely, in situ capture of freshwater from the atmosphere using hygroscopic electrolyte and electrolysis powered by solar or wind with a current density up to 574 mA cm−2. A prototype of such has been established and operated for 12 consecutive days with a stable performance at a Faradaic efficiency around 95%. This so-called direct air electrolysis (DAE) module can work under a bone-dry environment with a relative humidity of 4%, overcoming water supply issues and producing green hydrogen sustainably with minimal impact to the environment. The DAE modules can be easily scaled to provide hydrogen to remote, (semi-) arid, and scattered areas.

AB - Green hydrogen produced by water splitting using renewable energy is the most promising energy carrier of the low-carbon economy. However, the geographic mismatch between renewables distribution and freshwater availability poses a significant challenge to its production. Here, we demonstrate a method of direct hydrogen production from the air, namely, in situ capture of freshwater from the atmosphere using hygroscopic electrolyte and electrolysis powered by solar or wind with a current density up to 574 mA cm−2. A prototype of such has been established and operated for 12 consecutive days with a stable performance at a Faradaic efficiency around 95%. This so-called direct air electrolysis (DAE) module can work under a bone-dry environment with a relative humidity of 4%, overcoming water supply issues and producing green hydrogen sustainably with minimal impact to the environment. The DAE modules can be easily scaled to provide hydrogen to remote, (semi-) arid, and scattered areas.

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JO - Nature Communications

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Hydrogen production from the air

Abstract

UN SDGs

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