Urea-Modified Carbon Nitrides: Enhancing Photocatalytic Hydrogen Evolution by Rational Defect Engineering

Lau Vincent Wing-hei; Yu Victor Wen-zhe; Ehrat Florian; Botari Tiago; Moudrakovski Igor; Simon Thomas; Duppel Viola; Medina Elise; Stolarczyk Jacek K.; Feldmann Jochen; Blum Volker; Lotsch Bettina V.

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Urea-Modified Carbon Nitrides: Enhancing Photocatalytic Hydrogen Evolution by Rational Defect Engineering

机译：尿素修饰的碳氮化物：通过合理的缺陷工程提高光催化氢的释放

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The primary amine groups on the heptazine-based polymer melon, also known as graphitic carbon nitride (g-C3N4), can be replaced by urea groups using a two-step postsynthetic functionalization. Under simulated sunlight and optimum Pt loading, this urea-functionalized carbon nitride has one of the highest activities among organic and polymeric photocatalysts for hydrogen evolution with methanol as sacrificial donor, reaching an apparent quantum efficiency of 18% and nearly 30 times the hydrogen evolution rate compared to the nonfunctionalized counterpart. In the absence of Pt, the urea-derivatized material evolves hydrogen at a rate over four times that of the nonfunctionalized one. Since defects are conventionally accepted to be the active sites in graphitic carbon nitride for photocatalysis, the work here is a demonstrated example of defect engineering, where the catalytically relevant defect is inserted rationally for improving the intrinsic, rather than extrinsic, photocatalytic performance. Furthermore, the work provides a retrodictive explanation for the general observation that g-C3N4 prepared from urea performs better than those prepared from dicyandiamide and melamine. In-depth analyses of the spent photocatalysts and computational modeling suggest that inserting the urea group causes a metal-support interaction with the Pt cocatalyst, thus facilitating interfacial charge transfer to the hydrogen evolving centers.

机译：庚嗪类聚合物瓜上的伯胺基团（也称为石墨氮化碳（g-C3N4））可以通过两步后合成功能化被尿素基团取代。在模拟的阳光和最佳的Pt负载下，这种以尿素官能化的氮化碳在有机和聚合光催化剂中具有最高的活性之一，以甲醇为牺牲供体，可以产生氢，表观量子效率为18％，是氢释放速率的近30倍与未功能化的对应物相比在不存在Pt的情况下，尿素衍生化的物质放出氢气的速度是未官能化的物质的四倍。由于常规上公认缺陷是石墨氮化碳中用于光催化的活性位点，因此，本文的工作是缺陷工程的一个经过证明的示例，其中合理插入催化相关的缺陷以改善固有的（而非固有的）光催化性能。此外，这项工作为一般观察提供了追溯性的解释，即由尿素制得的g-C3N4的性能要优于由双氰胺和三聚氰胺制得的g-C3N4。对用过的光催化剂的深入分析和计算模型表明，插入尿素基团会导致金属载体与Pt助催化剂发生相互作用，从而促进界面电荷转移至氢演化中心。

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来源
《Advanced energy materials》 |2017年第12期|1602251.1-1602251.15|共15页
作者
Lau Vincent Wing-hei; Yu Victor Wen-zhe; Ehrat Florian; Botari Tiago; Moudrakovski Igor; Simon Thomas; Duppel Viola; Medina Elise; Stolarczyk Jacek K.; Feldmann Jochen; Blum Volker; Lotsch Bettina V.;
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作者单位

Max Planck Inst Solid State Res, Heisenbergstr 1, D-70569 Stuttgart, Germany;

Duke Univ, Dept Mech Engn & Mat Sci, Durham, NC 27708 USA;

LMU, Dept Phys, Photon & Optoelect Grp, Amalienstr 54, D-80799 Munich, Germany|LMU, Ctr Nanosci CeNS, Amalienstr 54, D-80799 Munich, Germany|Nanosyst Initiat Munich NIM, Schellingstr 4, D-80799 Munich, Germany;

Duke Univ, Dept Mech Engn & Mat Sci, Durham, NC 27708 USA;

Max Planck Inst Solid State Res, Heisenbergstr 1, D-70569 Stuttgart, Germany;

LMU, Dept Phys, Photon & Optoelect Grp, Amalienstr 54, D-80799 Munich, Germany|LMU, Ctr Nanosci CeNS, Amalienstr 54, D-80799 Munich, Germany|Nanosyst Initiat Munich NIM, Schellingstr 4, D-80799 Munich, Germany;

Max Planck Inst Solid State Res, Heisenbergstr 1, D-70569 Stuttgart, Germany;

Max Planck Inst Solid State Res, Heisenbergstr 1, D-70569 Stuttgart, Germany;

LMU, Dept Phys, Photon & Optoelect Grp, Amalienstr 54, D-80799 Munich, Germany|LMU, Ctr Nanosci CeNS, Amalienstr 54, D-80799 Munich, Germany|Nanosyst Initiat Munich NIM, Schellingstr 4, D-80799 Munich, Germany;

LMU, Dept Phys, Photon & Optoelect Grp, Amalienstr 54, D-80799 Munich, Germany|LMU, Ctr Nanosci CeNS, Amalienstr 54, D-80799 Munich, Germany|Nanosyst Initiat Munich NIM, Schellingstr 4, D-80799 Munich, Germany;

Duke Univ, Dept Mech Engn & Mat Sci, Durham, NC 27708 USA;

Max Planck Inst Solid State Res, Heisenbergstr 1, D-70569 Stuttgart, Germany|Nanosyst Initiat Munich NIM, Schellingstr 4, D-80799 Munich, Germany|Univ Munich, Dept Chem, Butenandtstr 5-13, D-81377 Munich, Germany;

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关键词
graphitic carbon nitride; metal-support interaction; photocatalysis; rational catalyst design; solar hydrogen;

机译：石墨氮化碳;金属与载体的相互作用;光催化;合理的催化剂设计;太阳能氢;

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机译：湿润环境中氮化物的合成：探讨优质光催化氢气进化反应的缺陷工程策略
3. Defect Engineering in Atomic-Layered Graphitic Carbon Nitride for Greatly Extended Visible-Light Photocatalytic Hydrogen Evolution [J] . Zhang Jin, Chen Jinwei, Wan Yingfei, ACS applied materials & interfaces . 2020,第12期

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4. Defects Engineering of Ru/MoS2-x and Its Enhanced Photocatalytic/Electrocatalytic Hydrogen Evolution Activity [C] . Yuxiao Zhang, Yasutaka Kuwahara, Kohsuke Mori 日本化学会春季年会講演予稿集 . 2018

机译：Ru / MOS2-X的缺陷工程及其增强的光催化/电催化氢气进化活性
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7. Urea-Modified Carbon Nitrides: Enhancing Photocatalytic Hydrogen Evolution by Rational Defect Engineering [O] . Vincent Wing-hei Lau, Victor Wen-zhe Yu, Florian Ehrat, 2017

机译：尿素改性的碳氮化物：通过理性缺陷工程增强光催化氢气进化

Urea-Modified Carbon Nitrides: Enhancing Photocatalytic Hydrogen Evolution by Rational Defect Engineering

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