Litcius/Paper detail

Activation of 2D MoS2 electrodes induced by high-rate lithiation processes

Tianzhu Liu, Georgian Melinte, Oleksandr Dolotko, Michael Knapp, Beatriz Mendoza‐Sánchez

2022Journal of Energy Chemistry22 citationsDOIOpen Access PDF

Abstract

MoS2 is a highly promising material for application in lithium-ion battery anodes due to its high theoretical capacity and low cost. However, problems with a fast capacity decay over cycling, especially at the first cycles, and poor rate performance have deterred its practical implementation. Herein, electrodes comprised solely of few-layers 2D MoS2 nanosheets have been manufactured by scalable liquid-phase exfoliation and spray deposition methods. The long-standing controversy questioning the reversibility of conversion processes of MoS2-based electrodes was addressed. Raman studies revealed that, in 2D MoS2 electrodes, conversion processes are indeed reversible, where nanostructure played a key role. Cycling of the electrodes at high current rates revealed an intriguing phenomenon consisting of a continuously increasing capacity after ca. 100–200 cycles. This phenomenon was comprehensively addressed by a variety of electrochemical and microscopy methods that revealed underlying physical activation mechanisms that involved a range of profound electrode structural changes. Activation mechanisms delivered a capacitive electrode of a superior rate performance and cycling stability, as compared to the corresponding pristine electrodes, and to MoS2 electrodes previously reported. Herein, we have devised a methodology to overcome the problem of cycling stability of 2D MoS2 electrodes. Moreover, activation of electrodes constitutes a methodology that could be applied to enhance the energy storage performance of electrodes based on other 2D nanomaterials, or combinations thereof, strategically combining chemistries to engineer electrodes of superior energy storage properties.

Topics & Concepts

ElectrodeMaterials scienceNanotechnologyAnodeNanomaterialsElectrochemistryBattery (electricity)Energy storageChemistryPhysicsQuantum mechanicsPower (physics)Physical chemistryAdvancements in Battery MaterialsMXene and MAX Phase MaterialsSupercapacitor Materials and Fabrication