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Abstract
This work explores the stable structures of 2D carbon nitrides (C1-xNx) with various C/N ratios using first principles calculations and a local particle-swarm optimization algorithm. It predicts that C1-xNx structures with low N-doping concentrations contain both graphitic and pyridinic N, explaining experimental observations. Pyridinic N is predominant at higher N concentrations. Low N-doping concentrations are energetically favorable, but this limitation can be overcome by using different C and N feedstocks and lower growth temperatures. The electronic properties of C1-xNx structures vary depending on N concentration and configuration, offering potential applications in diverse fields.
Publisher
npj Computational Materials
Published On
Aug 21, 2020
Authors
Saiyu Bu, Nan Yao, Michelle A. Hunter, Debra J. Searles, Qinghong Yuan
Tags
2D carbon nitrides
C/N ratios
N-doping
electronic properties
graphitic and pyridinic N

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