Local Electric Field Effects on Water Dissociation in Bipolar Membranes Studied Using Core–Shell Catalysts

IF 7 2区材料科学 Q2 CHEMISTRY, PHYSICAL

Chemistry of Materials Pub Date : 2024-12-02 DOI:10.1021/acs.chemmater.4c02190

Prasad V. Sarma, Boris V. Kramar, Lihaokun Chen, Sayantan Sasmal, Nicholas P. Weingartz, Jiawei Huang, James B. Mitchell, Minkyoung Kwak, Lin X. Chen, Shannon W. Boettcher

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Abstract

The local electric field strength is thought to affect the rate of water dissociation (WD) in bipolar membranes (BPMs) at the catalyst–nanoparticle surfaces. Here, we study core–shell nanoparticles, where the core is metallic, semiconducting, or insulating, to understand this effect. The nanoparticle cores were coated with a WD catalyst layer (TiO₂ or HfO₂) via atomic layer deposition (ALD), and the morphology was imaged with transmission electron microscopy. Irrespective of the core material, these core–shell catalysts displayed comparable WD overpotentials at optimal mass loading, despite the hypothesized differences in the electric field strength across the catalyst particle suggested by continuum electrostatic simulations. Substantial atomic interdiffusion between the core and shell was ruled out by X-ray absorption spectroscopy, X-ray photoelectron spectroscopy, and diffuse reflectance optical measurements. However, the optimal mass loading of catalyst was roughly 1 order of magnitude higher for the conductive and high dielectric core materials than for the low dielectric insulating cores. These findings are consistent with the hypothesis that electric field screening within the core material focuses the electric field drop between particles such that larger film thicknesses can be tolerated. Collectively, these data support the idea that it is the local electric field at the molecular level that controls proton-transfer rates and that the metal core/dielectric-shell constructs introduced here modulate that field. Further materials and synthetic design may enable optimization of the electric field strength across the proton-transfer trajectory at the material surface.

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用核壳催化剂研究了局部电场对双极膜中水解离的影响

局部电场强度被认为影响双极膜（bpm）在催化剂纳米颗粒表面的水解离（WD）速率。在这里，我们研究核壳纳米粒子，其中核是金属的，半导体的，或绝缘的，以了解这种效应。通过原子层沉积（ALD）在纳米颗粒芯上包裹一层WD催化剂（TiO2或HfO2），并用透射电镜对其形貌进行成像。不管核心材料是什么，这些核壳催化剂在最佳质量负载下显示出相似的WD过电位，尽管连续静电模拟表明催化剂颗粒上的电场强度存在假设差异。通过x射线吸收光谱、x射线光电子能谱和漫反射光学测量，排除了核和壳层之间大量的原子相互扩散。然而，对于导电和高介电芯材料，催化剂的最佳质量负载比低介电绝缘芯材料高约1个数量级。这些发现与假设一致，即在核心材料内的电场筛选聚焦粒子之间的电场下降，从而可以容忍更大的薄膜厚度。总的来说，这些数据支持这样一种观点，即控制质子转移速率的是分子水平上的局部电场，而本文介绍的金属核/介电壳结构调节了该电场。进一步的材料和合成设计可以优化材料表面质子转移轨迹上的电场强度。

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

Chemistry of Materials 工程技术-材料科学：综合

CiteScore

14.10

自引率

5.80%

发文量

929

审稿时长

1.5 months

期刊介绍： The journal Chemistry of Materials focuses on publishing original research at the intersection of materials science and chemistry. The studies published in the journal involve chemistry as a prominent component and explore topics such as the design, synthesis, characterization, processing, understanding, and application of functional or potentially functional materials. The journal covers various areas of interest, including inorganic and organic solid-state chemistry, nanomaterials, biomaterials, thin films and polymers, and composite/hybrid materials. The journal particularly seeks papers that highlight the creation or development of innovative materials with novel optical, electrical, magnetic, catalytic, or mechanical properties. It is essential that manuscripts on these topics have a primary focus on the chemistry of materials and represent a significant advancement compared to prior research. Before external reviews are sought, submitted manuscripts undergo a review process by a minimum of two editors to ensure their appropriateness for the journal and the presence of sufficient evidence of a significant advance that will be of broad interest to the materials chemistry community.