利用 CdS 纳米片进行光催化制氢和苄醇氧化的光催化剂设计原理

IF 2.9 4区 工程技术 Q2 CHEMISTRY, MULTIDISCIPLINARY Korean Journal of Chemical Engineering Pub Date : 2024-11-02 DOI:10.1007/s11814-024-00317-9
Ryun Na Kim, Jihun Kim, Gui-Min Kim, Doh C. Lee, Whi Dong Kim
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引用次数: 0

摘要

为了在利用光催化剂制氢的同时保持环保特性,研究重点是利用苯甲醇 (BzOH) 作为空穴清除剂,将其转化为有价值的化合物苯甲醛 (BA)。然而,与传统的空穴清除剂相比,BzOH 的氧化速度相对较慢,因此有必要设计定制的光催化剂。在本研究中,我们制备了 CdS 纳米片(NSs),并引入 Na2SO4-Na2SO3 和 BzOH 作为空穴清除剂,以调节光催化反应过程中的氧化半反应速率(OHR)。通过引入各种助催化剂,研究还原半反应速率(RHR)和氧化半反应速率的变化对制氢的影响。研究结果表明,助催化剂和空穴清除剂的选择会显著影响光催化反应中的速率决定步骤(RDS)。对于裸 CdS NSs,缓慢的 RHR 会导致 RDS 即 RHR,从而导致类似的产氢速率,而与清除剂类型无关。然而,在使用铂作为辅助催化剂时,由于 RHR 加速,RDS 转向 OHR,导致氢气产生率对清除剂类型高度敏感。因此,在使用氧化速率较慢的 BzOH 时,氢气产量会显著降低。这些研究结果表明,由于 BzOH 的氧化速率较慢,即使引入了优秀的助催化剂,要实现高产氢率仍具有根本性的挑战。因此,当务之急是开发价带水平较低的光催化剂材料,以获得较高的氧化能力。
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Photocatalyst Design Principles for Photocatalytic Hydrogen Production and Benzyl Alcohol Oxidation with CdS Nanosheets

To produce hydrogen using photocatalysts while maintaining environmentally friendly characteristics, research has focused on using benzyl alcohol (BzOH) as a hole scavenger to convert it into the valuable compound benzaldehyde (BA). However, due to the relatively slow oxidation rate of BzOH compared to conventional hole scavengers, tailored photocatalyst designs are necessary. In this study, we prepared CdS nanosheets (NSs) and introduced Na2SO4–Na2SO3 and BzOH as hole scavengers to adjust the oxidation half-reaction rate (OHR) during the photocatalytic reaction. Various co-catalysts were introduced to examine how changes in the reduction half-reaction (RHR) and OHR rates influence hydrogen production. The results reveal that the selection of co-catalyst and hole scavenger significantly influences the rate-determining step (RDS) in the photocatalytic reaction. For bare CdS NSs, the slow RHR results in the RDS being the RHR, leading to similar hydrogen production rate regardless of the scavenger type. However, with Pt as a co-catalyst, the RDS shifts to the OHR due to the accelerated RHR, inducing hydrogen production rate highly sensitive to the type of scavenger. Consequently, hydrogen production is significantly reduced when using BzOH, which has a slower oxidation rate. These findings suggest that achieving high hydrogen yields is fundamentally challenging with BzOH due to its slow oxidation rate, even with the introduction of excellent co-catalysts. Therefore, it is imperative to develop photocatalyst materials with lower valence band level for high oxidation power.

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来源期刊
Korean Journal of Chemical Engineering
Korean Journal of Chemical Engineering 工程技术-工程:化工
CiteScore
4.60
自引率
11.10%
发文量
310
审稿时长
4.7 months
期刊介绍: The Korean Journal of Chemical Engineering provides a global forum for the dissemination of research in chemical engineering. The Journal publishes significant research results obtained in the Asia-Pacific region, and simultaneously introduces recent technical progress made in other areas of the world to this region. Submitted research papers must be of potential industrial significance and specifically concerned with chemical engineering. The editors will give preference to papers having a clearly stated practical scope and applicability in the areas of chemical engineering, and to those where new theoretical concepts are supported by new experimental details. The Journal also regularly publishes featured reviews on emerging and industrially important subjects of chemical engineering as well as selected papers presented at international conferences on the subjects.
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