Formic Acid Electrooxidation on Palladium Nano-Layers Deposited onto Pt(111): Investigation of the Substrate Effect

IF 2.7 4区化学 Q3 CHEMISTRY, PHYSICAL

Electrocatalysis Pub Date : 2023-03-04 DOI:10.1007/s12678-023-00816-z

Vanessa L. Oliveira, Yvonne Soldo-Olivier, Edson A. Ticianelli, Marian Chatenet, Eric Sibert

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Abstract

The influence of Pd nano-layers electro-deposited onto Pt(111) single crystal has been systematically studied toward the formic acid electrochemical oxidation reaction in H₂SO₄ and HClO₄. The studied Pd_xML/Pt(111) surfaces (x = 1, 2, 5, and 16 monolayers (ML)) are all more active than Pt(111) toward formic acid oxidation, even if the activity is very sensitive to the Pd film thickness and morphology. In sulfate solution, the competitive adsorption of long-range ordered (bi)sulfate on the pseudomorphic Pd terraces effectively hinders the formic acid oxidation only on the thinnest films. We could observe the different roles of the (bi)sulfate adsorption on the first and on the following deposited Pd layers. The sulfate adsorption competitive role rapidly fades away beyond about 5 ML of equivalent thickness, due to the surface roughness increasing and terraces width diminishing. In perchlorate media, anions do not adsorb competitively with formic acid intermediates, allowing a larger activity of the formic acid oxidation up to about 5 ML. At higher thicknesses, the difference in activity between the two electrolytic media is reduced, and it drops in both electrolytes close to 0.5 V vs. RHE, where Pd surface oxides are formed. Coupling the electrochemical results with the Pd layer structural description previously obtained from in situ SXRD experiments, the outstanding activity of Pd_1ML/Pt(111) observed in perchloric solution can be explained by the ligand effect of the underlying platinum atoms on the first pseudomorphic Pd layer. This advantageous effect is lost for Pd deposits thicker than 1 ML.

Graphical Abstract

Abstract Image

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Pt(111)上钯纳米层的甲酸电氧化:衬底效应的研究

系统研究了电沉积在Pt(111)单晶上的Pd纳米层对H2SO4和HClO4中甲酸电化学氧化反应的影响。所研究的PdxML/Pt(111)表面(x = 1,2,5和16单层(ML))对甲酸氧化的活性都比Pt(111)更强，即使活性对Pd膜厚度和形貌非常敏感。在硫酸盐溶液中，远距离有序(bi)硫酸盐在伪晶钯平台上的竞争性吸附仅在最薄的膜上有效地阻止甲酸氧化。我们可以观察到(bi)硫酸盐在第一层和接下来的沉积层上的不同吸附作用。超过约5ml的等效厚度后，由于表面粗糙度增加和阶地宽度减小，硫酸盐吸附的竞争作用迅速消失。在高氯酸盐介质中，阴离子不会与甲酸中间体竞争吸附，从而使甲酸氧化活性更大，最高可达5ml。在更高的厚度下，两种电解质介质之间的活性差异减小，与形成Pd表面氧化物的RHE相比，两种电解质的活性差异都下降到接近0.5 V。将电化学结果与先前原位SXRD实验获得的Pd层结构描述相结合，发现Pd1ML/Pt(111)在高氯酸溶液中表现出的优异活性可以用第一层伪晶Pd层上铂原子的配体效应来解释。对于厚度大于1ml的Pd沉积层，这种有利的效果就消失了

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来源期刊

Electrocatalysis CHEMISTRY, PHYSICAL-ELECTROCHEMISTRY

CiteScore

4.80

自引率

6.50%

发文量

审稿时长

>12 weeks

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