
V 4 C 3 T x MXene: A promising active substrate for reactive surface modification and the enhanced electrocatalytic oxygen evolution activity
Author(s) -
Du ChengFeng,
Sun Xiaoli,
Yu Hong,
Fang Wei,
Jing Yao,
Wang Yonghui,
Li Shuiqing,
Liu Xianhu,
Yan Qingyu
Publication year - 2020
Publication title -
infomat
Language(s) - English
Resource type - Journals
ISSN - 2567-3165
DOI - 10.1002/inf2.12078
Subject(s) - overpotential , mxenes , materials science , oxygen evolution , amorphous solid , catalysis , ternary operation , substrate (aquarium) , oxide , hydroxide , chemical engineering , surface modification , nanotechnology , chemistry , crystallography , electrochemistry , metallurgy , biochemistry , oceanography , engineering , electrode , geology , computer science , programming language
Presented are the synthesis, characterizations, and reactive surface modification (RSM) of a novel nine atomic layered V 4 C 3 T x MXene. With the advantages of the multilayered V 4 C 3 T x MXene that can simultaneously support the RSM reaction and keep the inner skeleton stable, a series of amorphous Ni/Fe/V‐ternary oxide hydroxides thin layer can be successfully modified on the surface of the V 4 C 3 T x MXene (denoted as MOOH @V 4 C 3 T x , M = Ni, Fe, and V) without disrupting its original structure. Attributed to the in situ reconstruction of highly active oxide hydroxide layer, the nanohybrids exhibited an enhanced oxygen evolution reaction (OER) activity and excellent long‐time stability over 70 hours. In particular, a current density of 10 mA cm −2 can be reached by the nanohybrid with the optimized Ni/Fe ratio at an overpotential ( η ) as low as 275.2 mV, which is comparable to most of the state‐of‐the‐art OER catalysts and better than other MXene‐based derivatives. Demonstrated by the tunable physicochemical properties and excellent structural stability of these nanohybrids, we may envision the promising role of the M 4 X 3 ‐based MXenes as substrates for a wide range of energy conversion and storage materials.