Upside-Down Adsorption: The Counterintuitive Influences of Surface Entropy and Surface Hydroxyl Density on Hydrogen Spillover

IF 14.4 1区 化学 Q1 CHEMISTRY, MULTIDISCIPLINARY
Kelle D. Hart, Margaret J. Hollobaugh, Audrey M. Battiste, Tae Yong Yun, Angela Pathickal Abraham, Mohammad Hamidizirasefi, Ian M. Loscher and Bert D. Chandler*, 
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Abstract

Although hydrogen spillover is often invoked to explain anomalies in catalysis, spillover remains a poorly understood phenomenon. Hydrogen spillover (H*) is best described as highly mobile H atom equivalents that arise when H2 migrates from a metal nanoparticle to an oxide or carbon support. In the 60 years since its discovery, few methods have become available to quantify or characterize H*-support interactions. We recently showed in situ infrared spectroscopy and volumetric chemisorption can quantify reversible H2 adsorption on Au/TiO2 catalysts, where adsorbed hydrogen exists as H* and interacts with titania surface hydroxyl (TiOH) groups. Here, we report parallel thermogravimetric analysis and Fourier transform infrared spectroscopy methods for systematically manipulating the surface TiOH density. We examine the role of surface hydroxylation on spillover thermodynamics using van't Hoff studies to determine apparent adsorption enthalpies and entropies at constant H* coverage, which is necessary to maintain constant H* translational entropy. Although surface TiOH groups are the likely adsorption sites, the data show removing hydroxyl groups increases spillover. This surprising finding─that adsorption increases as the adsorption site density decreases─is associated with improved thermodynamics on dehydroxylated surfaces. A strong adsorption enthalpy–entropy correlation implicates the changing surface entropy of the titania support itself (i.e., an initial state effect) is deeply intertwined with the H* configurational entropy. These effects are surprising and should apply to all low-coverage adsorbates where entropy terms dominate more traditional enthalpic considerations. Moreover, this study points toward a kinetic test for invoking spillover in a reaction mechanism: namely, in situ dehydroxylation should enhance spillover processes.

Abstract Image

颠倒吸附:表面熵和表面羟基密度对氢溢出的反直觉影响
虽然氢溢出经常被用来解释催化过程中的异常现象,但溢出仍然是一种鲜为人知的现象。氢溢出(H*)的最佳描述是当 H2 从金属纳米粒子迁移到氧化物或碳支撑物时产生的高流动性 H 原子当量。自 H* 被发现以来的 60 年中,很少有方法可以量化或表征 H* 与支撑物之间的相互作用。我们最近的研究表明,原位红外光谱法和体积化学吸附法可以量化金/二氧化钛催化剂对 H2 的可逆吸附,其中吸附的氢以 H* 的形式存在,并与二氧化钛表面的羟基(TiOH)基团相互作用。在此,我们报告了并行热重分析和傅立叶变换红外光谱方法,用于系统地操纵表面 TiOH 密度。我们利用范特霍夫研究来确定恒定 H* 覆盖率下的表观吸附焓和熵,从而考察了表面羟基化对溢出热力学的作用。虽然表面 TiOH 基团可能是吸附位点,但数据显示去除羟基会增加溢出。随着吸附位点密度的降低,吸附量也会增加,这一令人惊讶的发现与脱羟基表面热力学的改善有关。强烈的吸附焓-熵相关性表明,二氧化钛支架本身表面熵的变化(即初始状态效应)与 H* 构型熵密切相关。这些效应令人吃惊,应该适用于所有低覆盖率吸附剂,在这些吸附剂中,熵项占主导地位的是更传统的焓考虑因素。此外,本研究还指出了在反应机制中引用溢出效应的动力学检验方法:即原位脱羟基反应应能增强溢出过程。
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来源期刊
CiteScore
24.40
自引率
6.00%
发文量
2398
审稿时长
1.6 months
期刊介绍: The flagship journal of the American Chemical Society, known as the Journal of the American Chemical Society (JACS), has been a prestigious publication since its establishment in 1879. It holds a preeminent position in the field of chemistry and related interdisciplinary sciences. JACS is committed to disseminating cutting-edge research papers, covering a wide range of topics, and encompasses approximately 19,000 pages of Articles, Communications, and Perspectives annually. With a weekly publication frequency, JACS plays a vital role in advancing the field of chemistry by providing essential research.
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