Interfacial Engineering of Ultrathin 2D/2D NiPS3/C3N5 Heterojunctions for Boosting Photocatalytic H2 Evolution

IF 13.5 2区化学 Q1 CHEMISTRY, PHYSICAL 物理化学学报 Pub Date : 2024-05-01 DOI:10.3866/PKU.WHXB202305043

Jiawei Hu , Kai Xia , Ao Yang , Zhihao Zhang , Wen Xiao , Chao Liu , Qinfang Zhang

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Abstract

This study focuses on exploring efficient photocatalysts for water splitting, which holds great potential for harnessing hydrogen (H₂) as a renewable energy source. Modulating the heterojunction interface is known to enhance charge carrier separation and solar energy utilization, thereby boosting photocatalytic activity. In this work, a mechanical mixing-assisted self-assembly approach was developed to construct a heterojunction between NiPS₃ (NPS) nanosheets (NSs) and C₃N₅ (CN) NSs. Specifically, two-dimensional (2D) NPS NSs were tightly deposited on 2D CN NSs surface to gain a 2D/2D heterostructure. The photocatalytic performance of the synthesized photocatalysts was determined by their ability to generate H₂ through water splitting, both in deionized (DI) water and seawater, under visible light. The resulting NPS NSs/CN NSs (NPS/CN) composites possessed boosted photocatalytic hydrogen evolution (PHE) activity related to CN NSs and NPS NSs. This improvement was assigned to the synergistic effect of increased light-harvesting capacity and heterojunction formation. Nevertheless, an excessive amount of deposited NPS NSs on the surface of CN NSs was found to reduce the light absorption of the CN NSs component in the NPS/CN composites, resulting in decreased PHE activity. Therefore, it was determined that an appropriate mass ratio between the two components is necessary to achieve excellent photocatalytic activity for the NPS/CN composites. The optimized photocatalyst, referred to as 3-NPS/CN, demonstrated the highest visible-light-driven PHE efficiency of 47.71 μmol·h⁻¹, which was 2385.50 times higher than that of CN NSs. Moreover, 3-NPS/CN also exhibited excellent PHE activity in seawater, with a rate of 8.99 μmol·h⁻¹. The photoelectrochemical, steady-state photoluminescence (PL), time-resolved PL (TR-PL), steady-state surface photovoltage (SPV) and time-resolved surface photovoltage (TPV) techniques were performed to investigate the charge separation and migration behaviors of various photocatalysts. Based on the characterization results, our group proposed a reasonable PHE mechanism. In the NPS/CN photocatalysts, photo-induced electrons rapidly migrated from the conduction band (CB) of CN NSs to the CB of NPS NSs due to the potential difference and strong interfacial electronic coupling between the two materials. The photogenerated electrons accumulated on the CB of the NPS NSs component efficiently reduced protons to generate H₂ molecules. Concurrently, photogenerated holes on the valence band (VB) of CN NSs and NPS NSs were consumed with the assistance of triethanolamine (TEOA) molecules. This study presents a facile method for fabricating 2D/2D heterostructured photocatalysts, which hold promise for efficient and robust implementation in energy applications.

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超薄2D/2D NiPS3/C3N5异质结促进光催化析氢的界面工程

本研究的重点是探索高效的水分解光催化剂，这在利用氢（H2）作为可再生能源方面具有很大的潜力。已知调制异质结界面可以增强载流子分离和太阳能利用，从而提高光催化活性。在这项工作中，开发了一种机械混合辅助自组装方法来构建NiPS3 （NPS）纳米片（NSs）和C3N5 (CN) NSs之间的异质结。具体来说，二维（2D） NPS NSs紧密沉积在二维CN NSs表面，获得2D/2D异质结构。合成的光催化剂的光催化性能取决于它们在可见光下在去离子水和海水中通过水裂解生成H2的能力。得到的NPS NSs/CN NSs （NPS/CN）复合材料具有与CN NSs和NPS NSs相关的光催化析氢活性。这种改进归因于增加的光收集能力和异质结形成的协同效应。然而，过量的NPS NSs沉积在CN NSs表面会降低NPS/CN复合材料中CN NSs组分的光吸收，导致PHE活性下降。因此，NPS/CN复合材料需要适当的质量比才能获得优异的光催化活性。优化后的3-NPS/CN光催化剂的可见光效率最高，为47.71 μmol·h−1，是CN NSs的2385.50倍。此外，3-NPS/CN在海水中也表现出良好的PHE活性，速率为8.99 μmol·h−1。采用光电化学、稳态光致发光（PL）、时间分辨光致发光（TR-PL）、稳态表面光电压（SPV）和时间分辨表面光电压（TPV）技术研究了各种光催化剂的电荷分离和迁移行为。基于表征结果，本课题组提出了合理的PHE机制。在NPS/CN光催化剂中，由于两种材料之间的电位差和强的界面电子耦合，光致电子从CN NSs的传导带（CB）迅速迁移到NPS NSs的传导带（CB）。光电子在NPS NSs组分的炭黑上积累，有效地还原质子生成H2分子。同时，在三乙醇胺（TEOA）分子的辅助下，CN NSs和NPS NSs的价带（VB）上的光生空穴被消耗掉。本研究提出了一种制造2D/2D异质结构光催化剂的简便方法，有望在能源应用中高效、稳健地实现。下载：下载高清图片（82KB）下载：下载全尺寸图片

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