Species mass transfer governs the selectivity of gas diffusion electrodes toward H2O2 electrosynthesis

Cui, Lele; Chen, Bin; Chen, Dongxu; He, Chen; Liu, Yi; Zhang, Hongyi; Qiu, Jian; Liu, Le; Jing, Wenheng; Zhang, Zhenghua

Species mass transfer governs the selectivity of gas diffusion electrodes toward H2O2 electrosynthesis

Lele Cui, Bin Chen, Dongxu Chen, Chen He, Yi Liu, Hongyi Zhang, Jian Qiu, Le Liu, Wenheng Jing () and Zhenghua Zhang ()
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Lele Cui: Tsinghua University
Bin Chen: Nanjing Tech University
Dongxu Chen: Tsinghua University
Chen He: Nanjing Tech University
Yi Liu: Tsinghua University
Hongyi Zhang: Tsinghua University
Jian Qiu: Nanjing Tech University
Le Liu: Tsinghua University
Wenheng Jing: Nanjing Tech University
Zhenghua Zhang: Tsinghua University

Nature Communications, 2024, vol. 15, issue 1, 1-15

Abstract: Abstract The meticulous design of advanced electrocatalysts and their integration into gas diffusion electrode (GDE) architectures is emerging as a prominent research paradigm in the H2O2 electrosynthesis community. However, it remains perplexing that electrocatalysts and assembled GDE frequently exhibit substantial discrepancies in H2O2 selectivity during bulk electrolysis. Here, we elucidate the pivotal role of mass transfer behavior of key species (including reactants and products) beyond the intrinsic properties of the electrocatalyst in dictating electrode-scale H2O2 selectivity. This tendency becomes more pronounced in high reaction rate (current density) regimes where transport limitations are intensified. By utilizing diffusion-related parameters (DRP) of GDEs (i.e., wettability and catalyst layer thickness) as probe factors, we employ both short- and long-term electrolysis in conjunction with in-situ electrochemical reflection-absorption imaging and theoretical calculations to thoroughly investigate the impact of DRP and DRP-controlled local microenvironments on O2 and H2O2 mass transfer. The mechanistic origins of diffusion-dependent conversion selectivity at the electrode scale are unveiled accordingly. The fundamental insights gained from this study underscore the necessity of architectural innovations for mainstream hydrophobic GDEs that can synchronously optimize mass transfer of reactants and products, paving the way for next-generation GDEs in gas-consuming electroreduction scenarios.

Date: 2024
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DOI: 10.1038/s41467-024-55091-3

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