Solar production of fuels from CO₂ with high efficiency and stability via in situ transformation of Bi electrocatalysts

Creators: Cheon, Woo Seok¹; Ji, Su Geun^{1, 2}; Kim, Jaehyun¹; Choi, Sungkyun¹; Yang, Jin Wook¹; Jun, Sang Eon¹; Kim, Changyeon¹; Bu, Jeewon¹; Park, Sohyeon¹; Lee, Tae Hyung¹; Wang, Jinghan¹; Kim, Jae Young¹; Lee, Sol A^{1, 3}; Kim, Jin Young¹; Jang, Ho Won^{1, 4}

1. Seoul National University
2. National Renewable Energy Laboratory
3. California Institute of Technology
4. Advanced Institute of Convergence Technology

Abstract

The sustainable electrocatalytic reduction of carbon dioxide into solar fuels offers a potential pathway to mitigate the impact of greenhouse gas-induced climate change. Here, we successfully achieved a high solar-to-fuel (STF) efficiency of 11.5% by integrating a low-cost tandem solar cell with robust, high-performance, non-precious metal-based electrocatalysts. The bismuth-based cathode exhibited a high formic acid selectivity of 97.2% at a potential of −1.1 V_RHE, along with an outstanding partial current density of 32.5 mA cm⁻². Furthermore, upon undergoing more than 24 hours of electrolysis, we observed an enhancement in the catalytic activity. Through comprehensive analysis including in situ Raman spectroscopy and density functional theory (DFT) calculations, we elucidated that the in situ transformation of bismuth into bismuth subcarbonate (BOC) induces multiple effects: (i) the formation of grain boundaries between phases with distinct lattice parameters, (ii) electronic modulation due to defect formation, and (iii) changes in the binding modes of key reaction intermediates on active sites, resulting in the stabilization of *OCHO species. The cause of these phase transformations was attributed to the structural similarity between the cathode template and BOC. The sustainability of the STF efficiency sets a new benchmark for all cost-effective photovoltaic-coupled electrochemical systems.

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Acknowledgement

This work was financially supported by the KRISS (Korea Research Institute of Standards and Science) MPI Lab. Program. And this work was also supported by the National Research Foundation of Korea (NRF) funded by the Ministry of Science and ICT (MSIT), South Korea (RS-2024-00405016, RS-2024-00421181). The Inter-University Semiconductor Research Center and Institute of Engineering Research at Seoul National University provided research facilities for this work.

Contributions

W. S. Cheon contributed to the research as a first author. He conducted experiments and wrote the manuscript under the supervision of H. W. Jang and J. Y. Kim. All authors contributed to the general discussion. S. G. Ji: resources, methodology. J. Kim: software, validation, formal analysis. S. Choi: formal analysis, methodology. J. W. Yang: methodology. S. E. Jun: conceptualization. C. Kim: methodology, conceptualization. J. Bu: visualization, formal analysis. S. Park: visualization, formal analysis. T. H. Lee: formal analysis. J. Wang: formal analysis. J. Y. Kim: formal analysis. S. A. Lee: investigation.

Data Availability

The data supporting the findings of this study are available within this article and its ESI,† or from the corresponding authors upon request.

Supplemental Material

Supplementary information

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