María Paula Salinas-Quezada, Jack K. Pedersen, Paula Sebastián-Pascual, Ib Chorkendorff, Krishanu Biswas, Jan Rossmeisl and María Escudero-Escribano
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引用次数: 0
Abstract
Understanding the catalytic activity of high-entropy alloys (HEAs) toward the conversion of small molecules such as carbon monoxide (CO) can provide insight into their structure–property relations. The identification of specific descriptors that govern the CO oxidation on HEAs is crucial to design new materials with customized compositions and structures. Herein, we have rationally assessed the CO oxidation mechanism on an extended AgAuCuPdPt HEA electrocatalyst under an acidic electrolyte. We compare the HEA performance with respect to platinum (Pt), palladium (Pd), and gold (Au) monometallic surfaces for CO oxidation. We also evaluated the same reaction on a binary AuPd alloy and a quaternary AuCuPdPt polycrystalline alloy with the aim of understanding the surface composition effects of the HEA. To provide insights into the descriptors controlling the CO oxidation mechanism and overpotential of the different alloy chemistry, we have combined cyclic voltammetry, surface-sensitive characterisation techniques and density functional theory (DFT) simulations. We show that silver (Ag) can improve the catalytic oxidation of CO by perturbing the *OH adsorption energy of Pd, leading to a lower onset potential. Additionally, we observed that Au segregates on the surface and that Cu is not stable at high applied potentials after CO oxidation. We highlight that HEA electrocatalysts are a valuable platform for designing more active and selective electrocatalyst surfaces.
了解高熵合金(HEAs)对一氧化碳(CO)等小分子转化的催化活性,有助于深入了解其结构-性能关系。确定支配 HEAs 上 CO 氧化的特定描述符对于设计具有定制成分和结构的新材料至关重要。在此,我们合理地评估了在酸性电解质条件下扩展的 AgAuCuPdPt HEA 电催化剂上的 CO 氧化机理。我们比较了铂 (Pt)、钯 (Pd) 和金 (Au) 单金属表面的 HEA 氧化 CO 的性能。我们还评估了二元 AuPd 合金和四元 AuCuPdPt 多晶合金上的相同反应,目的是了解 HEA 的表面成分效应。为了深入了解控制不同合金化学性质的 CO 氧化机制和过电位的描述因子,我们结合了循环伏安法、表面敏感表征技术和密度泛函理论(DFT)模拟。我们发现,银(Ag)可以通过扰动钯的*OH吸附能来改善 CO 的催化氧化,从而降低起始电位。此外,我们还观察到金会在表面发生偏析,而铜在 CO 氧化后的高电位下并不稳定。我们强调,HEA 电催化剂是设计更具活性和选择性的电催化剂表面的宝贵平台。