光催化
异质结
材料科学
制氢
分解水
铟
纳米技术
化学工程
热液循环
硫化物
制作
太阳能
硫化锌
量子产额
激子
锌
量子点
氢
光催化分解水
氧化还原
光电子学
量子效率
产量(工程)
硫化氢
光伏系统
水热合成
降级(电信)
催化作用
可见光谱
作者
Priya Yadav (2808076),Anil Chazhoor Asokan (19681104),Jyoti Yadav (301590),Boddu S. Naidu (6294116)
出处
期刊:
[Figshare (United Kingdom)]
日期:2025-11-08
标识
DOI:10.1021/acsaem.5c02585.s001
摘要
Hydrogen (H2) generation through photocatalytic water splitting continues to stand as one of the most promising alternatives to fossil fuels. For this purpose, photocatalysts must exhibit exceptional durability, efficiency, and the capability to harness solar energy fully for maximum output. In this work, we present the strategic design and fabrication of an advanced S-scheme heterojunction (HJ) photocatalyst comprising magnesium indium sulfide (MgIn2S4, MIS) and zinc sulfide (ZnS, ZS). This material was synthesized via a straightforward two-step hydrothermal route and evaluated for its effectiveness in driving light-induced H2 production from water splitting in the presence of a sacrificial agent. A series of characterizations illustrates the formation mechanism of the S-scheme HJ, the migration of photogenerated carriers, and related photocatalytic reactions. Experimental results confirm that the MIS/ZS S-scheme HJ can efficiently outperform pristine MIS and ZS. Among the MIS/ZS HJs (3, 5, 7, and 10 wt %), the 7-MIS/ZS HJ achieved the highest H2 evolution rate of 123.4 mmol·g–1·h–1, which is 8.8 and 28.05 times greater than those of pristine ZS and MIS, respectively. It also demonstrated an impressive apparent quantum yield of 22.42% at 370 nm, far surpassing those of its individual counterparts. This exceptional performance is attributed to the efficient S-scheme charge transfer, which promotes effective exciton separation and transport along with the robust structural stability inherited from ZS. Overall, this work provides a strong framework for designing durable, high-efficiency photocatalysts for water redox applications.
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