Stability and Performance of 3d Transition Metal Carbo-Sulfides: A Density Functional Theory Exploration for Li-Ion Battery Anodes

Linguo Lu; Alvaro Guerrero; Juan C. Velez Reyes; Jingsong Huang; Michael Naguib; Zhongfang Chen

doi:10.1002/celc.202500019

Stability and Performance of 3d Transition Metal Carbo-Sulfides: A Density Functional Theory Exploration for Li-Ion Battery Anodes

Linguo Lu, Alvaro Guerrero, Juan C. Velez Reyes, Jingsong Huang, Michael Naguib, Zhongfang Chen

Nanomaterials Theory Institute

Research output: Contribution to journal › Article › peer-review

Abstract

As the demand for high-performance and reliable energy storage devices continues to rise, identifying new anode materials is crucial for advancing Li-ion battery (LIB) technology. Inspired by recent experimental breakthroughs in synthesizing two-dimensional transition metal carbo-chalcogenides (2D-TMCCs), density functional theory calculations are performed to systematically explore their sulfide variants (TM₂S₂C) spanning all 3d transition metals in three possible phases. Through comprehensive evaluations of thermodynamic, dynamic, mechanical, and thermal stabilities, seven stable 2D-TMCC candidates are identified, four of which exhibit superior battery performance. Notably, V-based 2D-TMCCs across all three phases deliver moderate open-circuit voltages (OCV), efficient Li diffusion, and substantial capacities, making them promising candidates for industrial applications without requiring specific phase controls. A Cr-based 2D-TMCC (with sulfur atoms above carbon atoms) offers the highest capacity of 515.40 mAh g⁻¹, the lowest Li diffusion barrier, and an optimal OCV, highlighting its appealing potential as an anode material for LIBs. Furthermore, significant Li–Li spacing and pronounced electron delocalization in these four 2D-TMCCs suggest a reduced risk of dendrite formation. This work expands the 2D-TMCC family and identifies up-and-coming candidates for next-generation LIB anodes.

Original language	English
Article number	e202500019
Journal	ChemElectroChem
Volume	12
Issue number	19
DOIs	https://doi.org/10.1002/celc.202500019
State	Published - Oct 3 2025

Funding

This work was supported by the NSF Centre for the Advancement of Wearable Technologies (grant 1849243) and NASA (grant number 80NSSC19M0236). Part of this work was carried out at Oak Ridge National Laboratory's Center for Nanophase Materials Sciences, a US Department of Energy Office of Science User Facility. This research also used resources from the National Energy Research Scientific Computing Center, a DOE Office of Science User Facility supported by the Office of Science of the US Department of Energy under contract no. DE-AC02-05CH11231 using NERSC award BES-ERCAP0027465. This work was supported by the NSF Centre for the Advancement of Wearable Technologies (grant 1849243) and NASA (grant number 80NSSC19M0236). Part of this work was carried out at Oak Ridge National Laboratory's Center for Nanophase Materials Sciences, a US Department of Energy Office of Science User Facility. This research also used resources from the National Energy Research Scientific Computing Center, a DOE Office of Science User Facility supported by the Office of Science of the US Department of Energy under contract no. DE‐AC02‐05CH11231 using NERSC award BES‐ERCAP0027465.

Keywords

anode materials
density functional calculations
lithium-ion batteries
transition metal carbo-chalcogenides
two-dimensional materials

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10.1002/celc.202500019

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title = "Stability and Performance of 3d Transition Metal Carbo-Sulfides: A Density Functional Theory Exploration for Li-Ion Battery Anodes",

abstract = "As the demand for high-performance and reliable energy storage devices continues to rise, identifying new anode materials is crucial for advancing Li-ion battery (LIB) technology. Inspired by recent experimental breakthroughs in synthesizing two-dimensional transition metal carbo-chalcogenides (2D-TMCCs), density functional theory calculations are performed to systematically explore their sulfide variants (TM2S2C) spanning all 3d transition metals in three possible phases. Through comprehensive evaluations of thermodynamic, dynamic, mechanical, and thermal stabilities, seven stable 2D-TMCC candidates are identified, four of which exhibit superior battery performance. Notably, V-based 2D-TMCCs across all three phases deliver moderate open-circuit voltages (OCV), efficient Li diffusion, and substantial capacities, making them promising candidates for industrial applications without requiring specific phase controls. A Cr-based 2D-TMCC (with sulfur atoms above carbon atoms) offers the highest capacity of 515.40 mAh g−1, the lowest Li diffusion barrier, and an optimal OCV, highlighting its appealing potential as an anode material for LIBs. Furthermore, significant Li–Li spacing and pronounced electron delocalization in these four 2D-TMCCs suggest a reduced risk of dendrite formation. This work expands the 2D-TMCC family and identifies up-and-coming candidates for next-generation LIB anodes.",

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AB - As the demand for high-performance and reliable energy storage devices continues to rise, identifying new anode materials is crucial for advancing Li-ion battery (LIB) technology. Inspired by recent experimental breakthroughs in synthesizing two-dimensional transition metal carbo-chalcogenides (2D-TMCCs), density functional theory calculations are performed to systematically explore their sulfide variants (TM2S2C) spanning all 3d transition metals in three possible phases. Through comprehensive evaluations of thermodynamic, dynamic, mechanical, and thermal stabilities, seven stable 2D-TMCC candidates are identified, four of which exhibit superior battery performance. Notably, V-based 2D-TMCCs across all three phases deliver moderate open-circuit voltages (OCV), efficient Li diffusion, and substantial capacities, making them promising candidates for industrial applications without requiring specific phase controls. A Cr-based 2D-TMCC (with sulfur atoms above carbon atoms) offers the highest capacity of 515.40 mAh g−1, the lowest Li diffusion barrier, and an optimal OCV, highlighting its appealing potential as an anode material for LIBs. Furthermore, significant Li–Li spacing and pronounced electron delocalization in these four 2D-TMCCs suggest a reduced risk of dendrite formation. This work expands the 2D-TMCC family and identifies up-and-coming candidates for next-generation LIB anodes.

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Stability and Performance of 3d Transition Metal Carbo-Sulfides: A Density Functional Theory Exploration for Li-Ion Battery Anodes

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