Hollow MoS3 Nanospheres as Electrode Material for “Water‐in‐Salt” Li–Ion Batteries

Ting Quan,Yaolin Xu,Zhaolong Li,Nicolas Goubard‐Bretesché,Michael Tovar,Daniel Abou‐Ras,Yan Lu,Zdravko Kochovski,Holm Kirmse,Kai Skrodczky,Hongtao Yu,Marnix Wagemaker,Shilin Mei

doi:10.1002/batt.202000042

Abstract

AbstractThe use of “water‐in‐salt” electrolyte (WISE) (i. e., a highly concentrated aqueous solution) in rechargeable batteries has received increasing attention due to the significantly expanded electrochemical window compared to the limited voltage of conventional aqueous electrolytes. It enables the use of more positive/negative electrode material couples in aqueous batteries, resulting in an enhanced output voltage. However, one of the challenges is to identify promising anode materials for the “water‐in‐salt” Li‐ion batteries (WIS‐LIBs). Herein we for the first time demonstrate that MoS3, an amorphous chain‐like structured transitional metal trichalcogenide, is promising as anode in the WIS‐LIBs. In this work, hollow MoS3 nanospheres were synthesized via a scalable room‐temperature acid precipitation method. When applied in WIS‐LIBs, the prepared MoS3 achieved a high specific capacity of 127 mAh/g at the current density of 0.1 A/g and good stability over 1000 cycles. During operation, MoS3 underwent irreversible conversion to Li2MoO4 (with H2S and H2 evolution) during the initial Li ion uptake, and was then converted gradually to a more stable and reversible LixMoOy (2≤y≤4)) phase along cycling. Amorphous Li‐deficient Lix‐mMoOy/MoOz was formed upon delithiation. Nevertheless, MoS3 outperformed MoO3 in WIS‐LIBs, which could be accredited to its initial one‐dimensional molecular structure and the amorphous nature of the delithiated product facilitating charge transport. These results demonstrated a novel routine for synthesizing metal sulfides with hollow structures using a template‐based method and push forward the development of metal sulfides for aqueous energy storage applications.

Highlights

With the increasing energy demand and rapid depletion of fossil fuels, the exploration of sustainable and renewable energy resources such as solar, wind and tide has moved to the center attention
This thesis focuses on the study of high-performance hollow MoSx based electrode materials for aqueous energy storage systems, including supercapacitors and Li-ion batteries
In the first part of this thesis, highly dispersible hollow sandwich-structured carbon-MoS2-carbon nanoplates have been synthesized through an L-cysteine-assisted hydrothermal method by using gibbsite nanoplates as template and PDA as the carbon precursor

Summary

Introduction

With the increasing energy demand and rapid depletion of fossil fuels, the exploration of sustainable and renewable energy resources such as solar, wind and tide has moved to the center attention. Energy storage systems have become urgently needed to improve power reliability and quality as well as taking full advantage of high penetration of renewable energy sources.[1,2,3] The need to develop energy storage systems with low costs, low risks, high round-trip efficiency and long cycle life is recognized as an urgent priority. Batteries and supercapacitors are both regarded as the most promising electrochemical energy storage devices. Both supercapacitors and batteries consist of four main components: cathode, anode, electrolyte, and separator. 1.1 Aqueous electrolytes for supercapacitors and Li-ion batteries Electrolytes, as one of the key components of energy storage systems, provide ionic conductivity and facilitate charge compensation on each electrode. Electrolyte components directly determine the operational voltage of the cells, through which both the energy and power densities are affected

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