Photocatalytic Activity and Stability of Carbon Nitride-Pyrite Composites

IF 3 4区化学 Q3 CHEMISTRY, PHYSICAL

ChemPhotoChem Pub Date : 2024-12-23 DOI:10.1002/cptc.202400343

Julian Kaulbersch, Scott McGuigan, Jana Timm, Paul Maggard, Roland Marschall

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Abstract

In photocatalysis, the photoabsorber plays a crucial role in the reaction. The most important parameters are stability, cost and optical band gap. In this work, a prominent class of absorbers, namely carbon nitrides (CN), has been investigated. In the literature, CN is most often described as stable, although photodegradation has been observed. In order to retain the beneficial properties of CN while improving stability, a crystalline phase poly(triazine imide) (PTI) of carbon nitride was investigated and compared to polymeric CN in photocatalytic hydrogen generation experiments. In order to improve the charge separation for the photoinduced hydrogen evolution reaction, pyrite (FeS₂) was used as a surface co-catalyst with a loading of 1, 5 and 10 wt %. At the same time, any photodegradation products in solution were investigated by ion chromatography. Interestingly, PTI shows hardly any photocorrosion compared to defective carbon nitride, indicating its higher photostability in hydrogen evolution experiments. However, FeS₂ produces ammonium as a degradation product when synthesised from nitrogen-containing precursors. When made from nitrogen-free precursors, FeS₂ together with photostable PTI releases little ammonia, making it a photostable, earth-abundant composite for photocatalytic hydrogen generation.

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氮化碳-黄铁矿复合材料的光催化活性和稳定性

在光催化反应中，光吸收剂起着至关重要的作用。最重要的参数是稳定性、成本和光带隙。在这项工作中，研究了一类突出的吸收剂，即氮化碳（CN）。在文献中，CN通常被描述为稳定的，尽管已经观察到光降解。为了在保持CN的有利性能的同时提高稳定性，研究了氮化碳的结晶相聚三嗪亚胺（PTI），并在光催化制氢实验中与聚合CN进行了比较。为了改善光致析氢反应的电荷分离，以硫铁矿（FeS2）为表面助催化剂，负载分别为1、5和10 wt %。同时，用离子色谱法对溶液中的光降解产物进行了研究。有趣的是，与有缺陷的氮化碳相比，PTI几乎没有光腐蚀，这表明它在析氢实验中具有更高的光稳定性。然而，当由含氮前体合成时，FeS2会产生铵作为降解产物。当由无氮前体制成时，FeS2与光稳定的PTI一起释放很少的氨，使其成为光稳定的，丰富的用于光催化制氢的复合材料。

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来源期刊

ChemPhotoChem Chemistry-Physical and Theoretical Chemistry

CiteScore

5.80

自引率

5.40%

发文量

165

期刊介绍： Light plays a crucial role in natural processes and leads to exciting phenomena in molecules and materials. ChemPhotoChem welcomes exceptional international research in the entire scope of pure and applied photochemistry, photobiology, and photophysics. Our thorough editorial practices aid us in publishing authoritative research fast. We support the photochemistry community to be a leading light in science. We understand the huge pressures the scientific community is facing every day and we want to support you. Chemistry Europe is an association of 16 chemical societies from 15 European countries. Run by chemists, for chemists—we evaluate, publish, disseminate, and amplify the scientific excellence of chemistry researchers from around the globe.