Molecular-scale CO spillover on a dual-site electrocatalyst enhances methanol production from CO2 reduction

Cobalt phthalocyanine (CoPc) is recognized for catalysing electrochemical CO 2 reduction into methanol at high Faradaic efficiency but is subject to deactivation. Cobalt tetraaminophthalocyanine (CoPc-NH 2 ) shows improved stability, but its methanol Faradaic efficiency is below 30%. This study addr...

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Published inNature nanotechnology Vol. 20; no. 4; pp. 515 - 522
Main Authors Li, Jing, Zhu, Quansong, Chang, Alvin, Cheon, Seonjeong, Gao, Yuanzuo, Shang, Bo, Li, Huan, Rooney, Conor L., Ren, Longtao, Jiang, Zhan, Liang, Yongye, Feng, Zhenxing, Yang, Shize, Robert Baker, L., Wang, Hailiang
Format Journal Article
LanguageEnglish
Published London Nature Publishing Group UK 01.04.2025
Nature Publishing Group
Subjects
639/301/357
639/4077/4057
639/638/161
Carbon dioxide
Catalysts
Chemistry and Materials Science
Cobalt
Efficiency
Electrocatalysts
Materials Science
Methanol
Multi wall carbon nanotubes
Nanotechnology
Nanotechnology and Microengineering
Nanotubes
Spectroscopy
Spectrum analysis
Stability
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Summary:Cobalt phthalocyanine (CoPc) is recognized for catalysing electrochemical CO 2 reduction into methanol at high Faradaic efficiency but is subject to deactivation. Cobalt tetraaminophthalocyanine (CoPc-NH 2 ) shows improved stability, but its methanol Faradaic efficiency is below 30%. This study addresses these limitations in selectivity, reactivity and stability by rationally designing a dual-site cascade catalyst. Here we quantify the local concentration of CO, a key intermediate of the reaction, near a working CoPc-NH 2 catalyst and show that co-loading nickel tetramethoxyphthalocyanine (NiPc-OCH 3 ) with CoPc-NH 2 on multiwalled carbon nanotubes increases the generation and local concentration of CO. This dual-site cascade catalyst exhibits substantially higher performance than the original single-site CoPc-NH 2 /carbon nanotube catalyst, reaching a partial current density of 150 mA cm −2 and a Faradaic efficiency of 50% for methanol production. Kinetic analysis and in situ sum-frequency generation vibrational spectroscopy attribute this notable performance improvement to molecular-scale CO spillover from NiPc-OCH 3 sites to methanol-active CoPc-NH 2 sites. A dual-site electrocatalyst is developed to greatly enhance methanol production from CO 2 reduction via a cascade process, taking advantage of molecular-scale CO spillover.
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ISSN:1748-3387
1748-3395
1748-3395
DOI:10.1038/s41565-025-01866-8