Physicochemical Analysis of Cu(II)-Driven Electrochemical CO2 Reduction and its Competition with Proton Reduction.

IF 3.9 2区化学 Q2 CHEMISTRY, MULTIDISCIPLINARY

Chemistry - A European Journal Pub Date : 2024-10-21 DOI:10.1002/chem.202403321

Sk Samim Akhter, Diship Srivastava, Aman Mishra, Niladri Patra, Pankaj Kumar, Sumanta Kumar Padhi

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引用次数: 0

Abstract

The reduction of CO2 has become a key role in reducing greenhouse gas emissions in efforts to search for long-term responses to climate change. We report a a couple of CO2-reducing molecular catalysts based on earth-abundant copper complexes. These are [Cu(DPA)(PyNAP)] (1) and [Cu(DPA)(PyQl)] (2) (where, DPA = pyridine-2,6-dicarboxylic acid, PyNAP = 2-(pyridin-2-yl)-1,8-naphthyridine, and PyQl = 2-(pyridin-2-yl)quinoline). The copper metal-catalysed 2-electron reduction of CO2 to CO in the presence of 2-protons is challenging. These catalysts exhibit the production of CO gas in DMF/water mixtures, achieving an impressive faradaic efficiency of 84% and 72% for complex 1 and 2 at -1.7 V vs. SCE, respectively, for selective CO2 reduction. The production of H2 due to 2H+ + 2e- was also observed as a byproduct through the competitive proton reduction reaction. This was cross-verified by online gas and mass analysis. Our investigations confirmed the stability of the electrocatalysts under the electrocatalytic conditions. The mechanistic pathways were proposed to work with the EECC and ECEC (E: electrochemical and C: chemical) mechanisms. A CO2 insertion into an in-situ generated hydride from the Cu-center generates CO through the favourable path.

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Cu(II)-Driven Electrochemical CO2 Reduction 的物理化学分析及其与质子还原的竞争。

在寻求气候变化长期应对措施的过程中，二氧化碳减排已成为减少温室气体排放的关键。我们报告了几种基于地球丰富的铜络合物的二氧化碳还原分子催化剂。它们是 [Cu(DPA)(PyNAP)] (1) 和 [Cu(DPA)(PyQl)] (2)（其中，DPA = 吡啶-2,6-二羧酸，PyNAP = 2-(吡啶-2-基)-1,8-萘啶，PyQl = 2-(吡啶-2-基)喹啉）。在 2 质子存在的情况下，铜金属催化 2 电子将 CO2 还原成 CO 是一项挑战。这些催化剂能在 DMF/水混合物中产生 CO 气体，在-1.7 V 对 SCE 的条件下，复合物 1 和 2 的选择性 CO2 还原效率分别达到 84% 和 72%，令人印象深刻。通过竞争性质子还原反应，还观察到副产物 2H+ + 2e- 产生了 H2。在线气体和质量分析对此进行了交叉验证。我们的研究证实了电催化剂在电催化条件下的稳定性。我们提出了 EECC 和 ECEC（E：电化学，C：化学）机制的作用途径。二氧化碳从铜中心插入到原位生成的氢化物中，通过有利的路径生成一氧化碳。

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来源期刊

Chemistry - A European Journal 化学-化学综合

CiteScore

7.90

自引率

4.70%

发文量

1808

审稿时长

1.8 months

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