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Lithium Storage Mechanisms and Electrochemical Behavior of a Molybdenum Disulfide Nanoparticle Anode
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  • Xintong Li,
  • Wei Hao,
  • Hua Wang,
  • Tianyi Li,
  • Dimitrios Trikkaliotis,
  • Xinwei Zhou,
  • Dewen Hou,
  • Kai Chang,
  • Ahmed Hashem,
  • Yuzi Liu,
  • Zhenzhen Yang,
  • Saichao Cao,
  • Gyeong Hwang,
  • George Kyzas,
  • C. Buddie Mullins,
  • Christian Julien,
  • Likun Zhu
Xintong Li
Indiana University Purdue University at Indianapolis
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Wei Hao
UT Austin
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Hua Wang
Purdue University System
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Tianyi Li
Argonne National Laboratory
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Dimitrios Trikkaliotis
Democritus University of Thrace
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Xinwei Zhou
Argonne National Laboratory
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Dewen Hou
Argonne National Laboratory
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Kai Chang
IUPUI
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Ahmed Hashem
National Research Centre
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Yuzi Liu
Argonne National Laboratory
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Zhenzhen Yang
Argonne National Laboratory
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Saichao Cao
Shanghai Synchrotron Radiation Facility
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Gyeong Hwang
UT Austin
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George Kyzas
Democritus University of Thrace
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C. Buddie Mullins
UT Austin
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Christian Julien
Sorbonne Universit��
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Likun Zhu
Purdue University

Corresponding Author:[email protected]

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Abstract

This study investigates the electrochemical behavior of molybdenum disulfide (MoS2) as an anode in Li-ion batteries, focusing on the extra capacity phenomenon. Employing advanced characterization methods such as in situ and ex situ X-ray diffraction, Raman spectroscopy, X-ray photoelectron spectroscopy, and transmission electron microscopy, the research unravels the complex structural and chemical evolution of MoS2 throughout its cycling. A key discovery is the identification of a unique Li intercalation mechanism in MoS2, leading to the formation of reversible LixMoS2 phases that contribute to the extra capacity of the MoS2 electrode. Density function theory calculations suggest the potential for overlithiation in MoS2, predicting Li5MoS2 as the most energetically favorable phase within the lithiation-delithiation process. Additionally, the formation of a Li-rich phase on the surface of Li4MoS2 is considered energetically advantageous. After the first discharge, the battery system engages in two main reactions. One involves operation as a Li-sulfur battery within the carbonate electrolyte, and the other is the reversible intercalation and deintercalation of Li in LixMoS2. The latter reaction contributes to the extra capacity of the battery. The incorporation of reduced graphene oxide as a conductive additive in MoS2 electrodes notably improves their rate capability and cycling stability.
23 Jul 2024Submitted to Energy & Environmental Materials
23 Jul 2024Submission Checks Completed
23 Jul 2024Assigned to Editor
23 Jul 2024Review(s) Completed, Editorial Evaluation Pending
23 Jul 2024Reviewer(s) Assigned
11 Aug 2024Editorial Decision: Revise Major
03 Oct 20241st Revision Received
04 Oct 2024Submission Checks Completed
04 Oct 2024Assigned to Editor
04 Oct 2024Review(s) Completed, Editorial Evaluation Pending
04 Oct 2024Reviewer(s) Assigned
31 Oct 2024Editorial Decision: Accept