Novel MnO-Graphite Dual-Ion Battery and New Insights into Its Reaction Mechanism during Initial Cycle by Operando Techniques

Li-Na Wu; Shou-Yu Shen; Yu-Hao Hong; Chong-Heng Shen; Fa-Ming Han; Fang Fu; Xiao-Dong Zhou; Ling Huang; Jun-Tao Li; Shi-Gang Sun

doi:10.1021/acsami.9b01572

Novel MnO-Graphite Dual-Ion Battery and New Insights into Its Reaction Mechanism during Initial Cycle by Operando Techniques

ACS Appl Mater Interfaces. 2019 Apr 3;11(13):12570-12577. doi: 10.1021/acsami.9b01572. Epub 2019 Mar 20.

Authors

Li-Na Wu, Shou-Yu Shen, Yu-Hao Hong, Chong-Heng Shen, Fa-Ming Han, Fang Fu, Xiao-Dong Zhou¹, Ling Huang, Jun-Tao Li, Shi-Gang Sun

Affiliation

¹ Institute for Materials Research and Innovation, Department of Chemical Engineering , University of Louisiana at Lafayette , Lafayette , Louisiana 70504 , United States.

PMID: 30855934
DOI: 10.1021/acsami.9b01572

Abstract

Dual-ion battery complements lithium-ion batteries in terms of the use of inexpensive materials and ease to construct cells. To improve the safety and energy density of dual-ion battery, in this paper, a novel MnO-graphite dual-ion battery is reported for the first time. Microporous MnO materials are used as anode, which exhibits a low conversion potential and a low voltage hysteresis. The MnO-graphite dual-ion battery can deliver a capacity of 104 mAh g^-1 at 0.5C and exhibits good rate performances and cycling stability (capacity retention >93% after 300 cycles). A mechanism is proposed to explain the irreversibility in capacity during the initial cycle by using operando X-ray diffraction in combination with online electrochemical mass spectrometry and electrochemical impedance spectroscopy.

Keywords: EIS and mass spectroscopy investigations; MnO anode; dual-ion battery; initial cycle; operando XRD; reaction mechanism.