Issue 43, 2017

Nanoscale, conformal films of graphitic carbon nitride deposited at room temperature: a method for construction of heterojunction devices

Abstract

Graphitic carbon nitrides (GCNs) represent a family of 2D materials composed of carbon and nitrogen with variable amounts of hydrogen, used in a wide variety of applications. We report a method of room temperature thin film deposition which allows ordered GCN layers to be deposited on a very wide variety of substrates, including conductive glass, flexible plastics, nanoparticles and nano-structured surfaces, where they form a highly conformal coating on the nanoscale. Film thicknesses of below 20 nm are achievable. In this way we construct functional nanoscale heterojunctions between TiO2 nanoparticles and GCN, capable of producing H2 photocatalytically under visible light irradiation. The films are hydrogen rich, have a band gap around 1.7 eV, display transmission electron microscopy lattice fringes as well as X-ray diffraction peaks despite being deposited at room temperature, and show characteristic Raman and IR bands. We use cluster etching to reveal the chemical environments of C and N in GCN using X-ray photoelectron spectroscopy. We elucidate the mechanism of this deposition, which operates via sequential surface adsorption and reaction analogous to atomic layer deposition. The mechanism may have implications for current models of carbon nitride formation.

Graphical abstract: Nanoscale, conformal films of graphitic carbon nitride deposited at room temperature: a method for construction of heterojunction devices

Supplementary files

Article information

Article type
Communication
Submitted
31 Aug 2017
Accepted
16 Oct 2017
First published
17 Oct 2017
This article is Open Access
Creative Commons BY license

Nanoscale, 2017,9, 16586-16590

Nanoscale, conformal films of graphitic carbon nitride deposited at room temperature: a method for construction of heterojunction devices

S. A. Ladva, W. Travis, R. Quesada-Cabrera, M. Rosillo-Lopez, A. Afandi, Y. Li, R. B. Jackman, J. C. Bear, I. P. Parkin, C. Blackman, C. G. Salzmann and R. G. Palgrave, Nanoscale, 2017, 9, 16586 DOI: 10.1039/C7NR06489F

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