Engineering bimetallic interfaces and revealing the mechanism for carbon dioxide electroreduction to C3+ liquid chemicals

IF 7.9 2区综合性期刊 Q1 CHEMISTRY, MULTIDISCIPLINARY

Cell Reports Physical Science Pub Date : 2023-12-01 DOI:10.1016/j.xcrp.2023.101718

Yuting Xu, Michael B. Ross, Hongliang Xin, Fanglin Che

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Abstract

The reduction reaction of carbon dioxide (CO₂RR) to liquid C₃₊ chemicals is a potential net-zero carbon process that can increase local resiliency to power outages and fuel consumption. However, the mechanism and catalyst design rules to promote CO₂RR-to-C₃₊ are unknown. Engineering bimetallic interfaces (e.g., palladium/gold) to tune intermediate adsorption is promising for promoting C₃₊ formation. Our density functional theory calculations find that ∗CH₂ could be the key intermediate, and C₁–CH₂ coupling could be the rate-limiting step to generate C₃₊. High CO surface coverages can promote the bimetallic interfacial sites, lower the energetics of the C₁–CH₂ coupling step, and enhance C₃₊ formation. We further construct a volcano plot of C₁–CH₂ kinetics as a function of the binding strength of key intermediate ∗CH₂ via engineering the d-band center of the interfacial site. Our findings could guide the rational design of bimetallic interfaces and their near-surface microenvironment for enhancing CO₂RR-to-C₃₊.

Abstract Image

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设计双金属界面，揭示二氧化碳电还原为C3+液体化学品的机理

二氧化碳(CO2RR)对液态C3+化学物质的还原反应是一个潜在的净零碳过程，可以提高当地对停电和燃料消耗的弹性。然而，促进co2rr转化为c3 +的机理和催化剂设计规则尚不清楚。工程双金属界面(如钯/金)调节中间吸附有望促进C3+的形成。我们的密度泛函理论计算发现，∗CH2可能是关键中间体，C1-CH2耦合可能是生成C3+的限速步骤。高CO表面覆盖度促进了双金属界面位的形成，降低了C1-CH2耦合过程的能量，促进了C3+的形成。我们进一步构建了C1-CH2动力学的火山图，这是关键中间体∗CH2结合强度的函数，通过工程设计界面位置的d波段中心。本研究结果可以指导双金属界面及其近表面微环境的合理设计，以增强co2rr - c3 +。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Cell Reports Physical Science Energy-Energy (all)

CiteScore

11.40

自引率

2.20%

发文量

388

审稿时长

62 days

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