Oxygen Adsorption at the Electrochemical Metal/Water Interface: Au(111) vs Pt(111)

Vanessa J., Bukas, Alexandra M., Dudzinski, Elias, Diesen, Karsten, Reuter
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Abstract

Reaction mechanisms in heterogeneous electrocatalysis have been known to change through the local field that arises at the electrified metal/liquid interface. First-principles simulations specifically predict that such a field can significantly modify the surface binding of dipolar or polarizable intermediates along a catalytic reaction path. This dependence can then lead to a corresponding dependence upon applied potential even for so-called ‘chemical’ reaction steps that do not involve an explicit proton-coupled-electron-transfer such as, e.g., O2 adsorption during the oxygen reduction reaction (ORR). And yet, such effects are only now starting to be systematically explored at the atomic level. In this study, we directly compare the potential dependence of O2 adsorption as the first ORR step on Au(111) vs Pt(111). Using ab initio molecular dynamics and free energy sampling, we find that the strong dependence previously predicted at Au(111) is specifically lost at Pt(111). By decoupling the O2 potential response into contributions of different physical origin, we explain this contrast through the inherently different reactivity of the two metals. We finally discuss an indirect effect of potential through the surface coverage that can promote a dissociative-type mechanism at Pt(111) by breaking the O-O bond already during the first step of the ORR mechanism. Our results thus overall suggest a more complex mechanistic picture than hitherto anticipated; one where the local field may manifest in different, yet potentially equally important, ways over different systems.
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电化学金属/水界面的氧气吸附:金(111)与铂(111)
众所周知,异相电催化的反应机制会因电化金属/液体界面上产生的局部场而改变。第一原理模拟特别预测,这种场可以显著改变催化反应路径上双极性或可极化中间产物的表面结合。这种依赖性甚至会导致所谓的 "化学 "反应步骤对外加电势产生相应的依赖性,而这种反应步骤并不涉及明确的质子耦合电子转移,例如氧还原反应(ORR)中的氧气吸附。然而,人们现在才开始在原子水平上系统地探索这种效应。在本研究中,我们直接比较了作为氧还原反应第一步的 O2 吸附在 Au(111) 和 Pt(111) 上的电位依赖性。通过使用 ab initio 分子动力学和自由能采样,我们发现之前在 Au(111)上预测的强烈依赖性在 Pt(111)上具体消失了。通过将 O2 电位响应解耦为不同物理来源的贡献,我们通过两种金属固有的不同反应性来解释这种对比。最后,我们讨论了电位通过表面覆盖层产生的间接效应,这种效应可以在 ORR 机制的第一步就切断 O-O 键,从而促进 Pt(111) 的解离型机制。因此,我们的研究结果总体上表明了一种比迄今为止所预期的更为复杂的机理图景;在这种图景中,局部场可能会以不同但可能同样重要的方式在不同的系统中表现出来。
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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