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Self‐Powered System for H<sub>2</sub> Production and Biomass Upgrading

Shao‐Qing Liu, Shiyan Xie, Shuwen Wu, Yang Yang, Peng‐Xia Lei, Shuiping Luo, Renfei Feng, Xian‐Zhu Fu, Jing‐Li Luo

2024Advanced Functional Materials17 citationsDOIOpen Access PDF

Abstract

Abstract Hydrazine‐oxidation‐assisted self‐powered H 2 generation system greatly expands the applicability of hydrogen production technology. However, the high cost of hydrazine greatly impedes the widespread adoption of hydrazine‐contained energy systems for large‐scale H 2 production. Besides, the gaseous products of hydrazine splitting, comprising a mixture of H 2 and N 2 , necessitate energy‐intensive downstream separation. Here, taking advantage of a low‐potential furfural oxidation reaction (FOR) on the Cu electrode, a self‐powered H 2 production system by integrating a direct furfural fuel cell (DFFC) and a bipolar H 2 production electrolyser is reported. Ru‐dispersed Cu nanowire with remarkable catalytic activity is developed as a hydrogen evolution reaction (HER) catalyst to couple with the FOR. The HER‐FOR electrolyzer achieves bipolar H 2 production with an apparent 200% Faradaic efficiency, attaining a current density of 100 mA cm −2 with a low cell voltage of 0.43 V. The DFFC displays an open circuit potential of 0.969 V and a peak power density up to 193 mW cm −2 . Inspired by the bipolar H 2 production that eliminates the gas separation, a self‐powered system utilizing furfural as the sole consumable, which yields a pure H 2 production rate of 6 mmol h −1 m −2 is demonstrated. This work provides a new avenue for constructing self‐powered H 2 production systems.

Topics & Concepts

Biomass (ecology)Production (economics)Environmental scienceWaste managementProcess engineeringEngineeringAgronomyEconomicsBiologyMacroeconomicsElectrocatalysts for Energy ConversionHybrid Renewable Energy SystemsHydrogen Storage and Materials
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