通过热蒸汽冷凝沉积的均匀石墨相氮化碳薄膜中的多能级跃迁实现高效发射。

Efficient emission facilitated by multiple energy level transitions in uniform graphitic carbon nitride films deposited by thermal vapor condensation.

作者信息

Bian Juncao, Li Jianfu, Kalytchuk Sergii, Wang Yu, Li Qian, Lau Tsz Chun, Niehaus Thomas A, Rogach Andrey L, Zhang Rui-Qin

机构信息

Department of Physics and Materials Science and Centre for Functional Photonics (CFP), City University of Hong Kong, No 83, Tat Chee Avenue, Hong Kong S.A.R. (China).

出版信息

Chemphyschem. 2015 Apr 7;16(5):954-9. doi: 10.1002/cphc.201402898. Epub 2015 Feb 23.

DOI:10.1002/cphc.201402898

PMID:25707008

Abstract

Graphitic carbon nitride (g-CN) films are important components of optoelectronic devices, but current techniques for their production, such as drop casting and spin coating, fail to deliver uniform and pinhole-free g-CN films on solid substrates. Here, versatile, cost-effective, and large-area growth of uniform and pinhole-free g-CN films is achieved by using a thermal vapor condensation method under atmospheric pressure. A comparison of the X-ray diffraction and Fourier transform infrared data with the calculated infrared spectrum confirmed the graphitic build-up of films composed of tri-s-triazine units. These g-CN films possess multiple active energy states including π*, π, and lone-pair states, which facilitate their efficient (6% quantum yield in the solid state) photoluminescence, as confirmed by both experimental measurements and theoretical calculations.

摘要

石墨相氮化碳（g-CN）薄膜是光电器件的重要组成部分，但目前用于制备它们的技术，如滴铸法和旋涂法，无法在固体基板上制备出均匀且无针孔的g-CN薄膜。在此，通过在大气压下使用热蒸汽冷凝法实现了均匀且无针孔的g-CN薄膜的通用、经济高效且大面积生长。将X射线衍射和傅里叶变换红外数据与计算出的红外光谱进行比较，证实了由三-s-三嗪单元组成的薄膜的石墨结构。这些g-CN薄膜具有多个活性能态，包括π*、π和孤对电子态，这有助于它们实现高效的（固态量子产率为6%）光致发光，实验测量和理论计算均证实了这一点。

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通过热蒸汽冷凝沉积的均匀石墨相氮化碳薄膜中的多能级跃迁实现高效发射。

Efficient emission facilitated by multiple energy level transitions in uniform graphitic carbon nitride films deposited by thermal vapor condensation.

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