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Interfacial Defect Engineering for Improved Portable Zinc–Air Batteries with a Broad Working Temperature
Author(s) -
An Li,
Huang Bolong,
Zhang Yu,
Wang Rui,
Zhang Nan,
Dai Tengyuan,
Xi Pinxian,
Yan ChunHua
Publication year - 2019
Publication title -
angewandte chemie international edition
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 5.831
H-Index - 550
eISSN - 1521-3773
pISSN - 1433-7851
DOI - 10.1002/anie.201903879
Subject(s) - bifunctional , non blocking i/o , density functional theory , oxygen evolution , materials science , electron transfer , catalysis , nanowire , chemical engineering , electrode , redox , oxygen reduction reaction , oxygen , nanotechnology , electrochemistry , chemistry , computational chemistry , metallurgy , organic chemistry , engineering , biochemistry
Atomic‐thick interfacial dominated bifunctional catalyst NiO/CoO transition interfacial nanowires (TINWs) with abundant defect sites display high electroactivity and durability in the oxygen evolution reaction (OER) and the oxygen reduction reaction (ORR). Density functional theory (DFT) calculations show that the excellent OER/ORR performance arises from the electron‐rich interfacial region coupled with defect sites, thus enabling a fast‐redox rate with lower activation barrier for fast electron transfer. When assembled as an air‐electrode, NiO/CoO TINWs delivered the high specific capacity of 842.58 mAh g Zn −1 , the large energy density of 996.44 Wh kg Zn −1 with long‐time stability of more than 33 h (25 °C), and superior performance at low (−10 °C) and high temperature (80 °C).