| Literature DB >> 30357972 |
Huimin Yu1, Xin Yang2, Xu Xiao1, Ming Chen3, Qinghua Zhang4, Liang Huang1, Jiabing Wu1, Tianqi Li1, Shuangming Chen5, Li Song5, Lin Gu4, Bao Yu Xia6, Guang Feng3, Jia Li2, Jun Zhou1.
Abstract
2D transition metal nitrides, especially nitrogen-rich tungsten nitrides (Wx Ny , y > x), such as W3 N4 and W2 N3 , have a great potential for the hydrogen evolution reaction (HER) since the catalytic activity is largely enhanced by the abundant WN bonding. However, the rational synthesis of 2D nitrogen-rich tungsten nitrides is challenging due to the large formation energy of WN bonding. Herein, ultrathin 2D hexagonal-W2 N3 (h-W2 N3 ) flakes are synthesized at atmospheric pressure via a salt-templated method. The formation energy of h-W2 N3 can be dramatically decreased owing to the strong interaction and domain matching epitaxy between KCl and h-W2 N3 . 2D h-W2 N3 demonstrates an excellent catalytic activity for cathodic HER with an onset potential of -30.8 mV as well as an overpotential of -98.2 mV for 10 mA cm-2 .Entities:
Keywords: 2D materials; atmospheric-pressure synthesis; electrocatalysis; nitrogen-rich; transition metal nitrides
Year: 2018 PMID: 30357972 DOI: 10.1002/adma.201805655
Source DB: PubMed Journal: Adv Mater ISSN: 0935-9648 Impact factor: 30.849