碳纳米管@碳化硅同轴异质结纳米管非金属光催化剂产氢性能(英文)
发布时间:2021-11-13 23:20
近年来,光催化裂解水产氢(H2)引起了广泛的关注.储量丰富,环境友好的非金属无机半导体β-SiC(立方相碳化硅)具有适当的带隙(Eg=2.4 eV, ECB=-0.9 V),是一种潜在的光催化剂.受限于SiC光催化剂内部光生电子-空穴对的快速复合, SiC光催化剂的效率较低.已有的关于SiC光催化剂改性的报道主要包括构建纳米SiC,构建SiC异质结,构建碳/SiC材料杂化材料.进一步的研究表明, SiC与碳材料之间通过紧密的界面接触形成了肖特基结,能将SiC表面的光生电子快速转移,抑制光生电子-空穴对的快速复合,从而提高光催化分解水产氢的活性.另一方面,碳纳米管(CNTs)具有良好的电子导电性,一维有序的管腔所形成的电子快速传导路径.因此,将半导体光催化剂与CNTs复合,是一种制备先进的光催化剂的有效策略.本文利用Si蒸气与CNTs之间的气-固反应,在CNTs表面原位生长SiC纳米包覆层,成功地制备了一维同轴核-壳CNTs@SiC纳米管.高分辨率透射电子显微镜图像表明, SiC与CNTs之间是通过Si-C共价键原子接触,并得到X射线光电子能谱...
【文章来源】:Chinese Journal of Catalysis. 2020,41(01)北大核心EISCICSCD
【文章页数】:10 页
【文章目录】:
1. Introduction
2. Experimental
2.1. Material synthesis
2.2. Characterization
2.3. Photoelectrochemical measurements
2.4. PC water splitting
3. Results and discussion
3.1. Structure and composition of the photocatalysts
3.2. Optical properties and photoelectricities of the photocatalysts
3.3. PC activities of the photocatalysts
3.4. Discussion of the mechanism
4. Conclusions
本文编号:3493911
【文章来源】:Chinese Journal of Catalysis. 2020,41(01)北大核心EISCICSCD
【文章页数】:10 页
【文章目录】:
1. Introduction
2. Experimental
2.1. Material synthesis
2.2. Characterization
2.3. Photoelectrochemical measurements
2.4. PC water splitting
3. Results and discussion
3.1. Structure and composition of the photocatalysts
3.2. Optical properties and photoelectricities of the photocatalysts
3.3. PC activities of the photocatalysts
3.4. Discussion of the mechanism
4. Conclusions
本文编号:3493911
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