Electrolytic Hydrogen Release from Hydrogen Boride Sheets

Author:

Kawamura Satoshi1,Yamaguchi Akira1ORCID,Miyazaki Keisuke1,Ito Shin‐ichi2,Watanabe Norinobu3,Hamada Ikutaro4ORCID,Kondo Takahiro256ORCID,Miyauchi Masahiro1ORCID

Affiliation:

1. Department of Materials Science and Engineering School of Materials and Chemical Technology Tokyo Institute of Technology Meguro‐ku Tokyo 152–8552 Japan

2. Department of Materials Science Institute of Pure and Applied Sciences University of Tsukuba Tsukuba 305‐8573 Japan

3. Graduate school of Science and Technology University of Tsukuba Tsukuba 305‐8573 Japan

4. Department of Precision Engineering Graduate School of Engineering Osaka University Suita Osaka 565‐0871 Japan

5. The Advanced Institute for Materials Research Tohoku University Sendai Miyagi 980‐8577 Japan

6. Tsukuba Research Center for Energy Materials Science Institute of Pure and Applied Sciences and R&D Center for Zero CO2 Emission Functional Materials University of Tsukuba Tsukuba 305‐8573 Japan

Abstract

AbstractSolid‐state hydrogen storage materials are safe and lightweight hydrogen carriers. Among the various solid‐state hydrogen carriers, hydrogen boride (HB) sheets possess a high gravimetric hydrogen capacity (8.5 wt%). However, heating at high temperatures and/or strong ultraviolet illumination is required to release hydrogen (H2) from HB sheets. In this study, the electrochemical H2 release from HB sheets using a dispersion system in an organic solvent without other proton sources is investigated. H2 molecules are released from the HB sheets under the application of a cathodic potential. The Faradaic efficiency for H2 release from HB sheets reached >90%, and the onset potential for H2 release is −0.445 V versus Ag/Ag+, which is more positive than those from other proton sources, such as water or formic acid, under the same electrochemical conditions. The total electrochemically released H2 in a long‐time experiment reached ≈100% of the hydrogen capacity of HB sheets. The H2 release from HB sheets is driven by a small bias; thus, they can be applied as safe and lightweight hydrogen carriers with economical hydrogen release properties.

Funder

New Energy and Industrial Technology Development Organization

Publisher

Wiley

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