Sulfone‐functionalized stable molecular single crystals for photocatalytic hydrogen evolution

SusMat Pub Date : 2024-06-10 DOI:10.1002/sus2.220

Xunliang Hu, Xiaoju Yang, Bingyi Song, Zhen Zhan, Ruixue Sun, Yantong Guo, Li‐Ming Yang, Xuan Yang, Chun Zhang, Irshad Hussain, Xiaoyang Wang, Bien Tan

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Abstract

Highly crystalline organic semiconductors are ideal materials for photocatalytic hydrogen evolution in water splitting. However, the instability and complex synthesis processes of most reported organic molecule‐based photocatalysts restrict their applications. In this study, we introduce benzo [1,2‐b:4,5‐bʹ] bis [1] benzothiophene‐3,9‐dicarboxylic acid, 5,5,11,11‐tetraoxide (FSOCA), a highly crystalline, stable molecular crystal that is easy to synthesize and serves as an efficient photocatalyst for the hydrogen evolution reaction. FSOCA exhibits high efficiency in sacrificial hydrogen evolution reaction (760 µmol h−1, 76 mmol g−1 h−1 at 330 mW cm−2; 570 µmol h−1, 57 mmol g−1 h−1 at 250 mW cm−2), and FSOCA remains stable during photocatalysis for up to 400 h. Experiments and theoretical studies confirmed the presence of hydrogen bonds between the sulfone group and the sacrificial agent (ascorbic acid). This interaction significantly improved the oxidation reaction kinetics and boosted the photocatalytic performance. This study presents a scalable and convenient approach to synthesize highly crystalline, active, and stable organic photocatalysts with potential applications in large‐scale photocatalysis.

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用于光催化氢进化的砜功能化稳定分子单晶体

高结晶有机半导体是在水分离过程中进行光催化氢进化的理想材料。然而，大多数已报道的基于有机分子的光催化剂的不稳定性和复杂的合成过程限制了它们的应用。在本研究中，我们介绍了苯并[1,2-b:4,5-bʹ]双[1]苯并噻吩-3,9-二羧酸，5,5,11,11-四氧化物（FSOCA），这是一种高度结晶、稳定的分子晶体，易于合成，可作为氢进化反应的高效光催化剂。FSOCA 在牺牲氢进化反应中表现出很高的效率（330 mW cm-2 时为 760 µmol h-1，76 mmol g-1 h-1；250 mW cm-2 时为 570 µmol h-1，57 mmol g-1 h-1），而且 FSOCA 在光催化过程中可保持稳定长达 400 小时。这种相互作用大大改善了氧化反应动力学，提高了光催化性能。这项研究提出了一种可扩展的、方便的方法来合成高结晶、高活性和高稳定性的有机光催化剂，具有在大规模光催化中应用的潜力。

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