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Main Authors: Sultana, Nishat, Amin, Abdullah A., Payton, Eric J., Kim, Woo Kyun
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2504.08953
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author Sultana, Nishat
Amin, Abdullah A.
Payton, Eric J.
Kim, Woo Kyun
author_facet Sultana, Nishat
Amin, Abdullah A.
Payton, Eric J.
Kim, Woo Kyun
contents In this study, we employ first-principles density functional theory (DFT) calculations to investigate the electrochemical properties of Nb2C and Nb2CO2 MXenes as potential anode materials for sodium-ion (SIBs) and lithium-ion batteries (LIBs). Our findings reveal that Li and Na intercalation primarily modifies the electronic properties of Nb2C without inducing significant structural distortions, as indicated by Raman intensity variations. Adsorption energy calculations show that the T4 and H3 sites are the most favorable for metal intercalation, with Nb2CO2 exhibiting stronger adsorption due to oxygen functionalization. We find that Nb2C offers lower diffusion barriers, especially for Na ions, making it a promising candidate for fast-charging SIBs. In contrast, Nb2CO2 enhances charge retention through stronger electrostatic interactions but introduces higher migration resistance. Electronic structure analysis confirms the metallic nature of both MXenes, ensuring efficient electron transport. Open-circuit voltage (OCV) calculations indicate that Nb2CO2 exhibits higher OCV values than Nb2C, highlighting the role of surface functionalization in tuning electrochemical performance. Our study suggests that, while Li-based systems achieve slightly higher theoretical capacities, Na-based systems exhibit comparable performance, reinforcing the viability of sodium-ion batteries as a cost-effective alternative. Overall, our results demonstrate that Nb2C is better suited for rapid ion transport, whereas Nb2CO2 offers enhanced charge retention. These insights provide a foundation for the optimization of MXene-based electrodes for next-generation high performance energy storage applications.
format Preprint
id arxiv_https___arxiv_org_abs_2504_08953
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Insights into Nb2C and Nb2CO2 as high-performance anodes for sodium- and lithium-ion batteries: An ab initio investigation
Sultana, Nishat
Amin, Abdullah A.
Payton, Eric J.
Kim, Woo Kyun
Materials Science
In this study, we employ first-principles density functional theory (DFT) calculations to investigate the electrochemical properties of Nb2C and Nb2CO2 MXenes as potential anode materials for sodium-ion (SIBs) and lithium-ion batteries (LIBs). Our findings reveal that Li and Na intercalation primarily modifies the electronic properties of Nb2C without inducing significant structural distortions, as indicated by Raman intensity variations. Adsorption energy calculations show that the T4 and H3 sites are the most favorable for metal intercalation, with Nb2CO2 exhibiting stronger adsorption due to oxygen functionalization. We find that Nb2C offers lower diffusion barriers, especially for Na ions, making it a promising candidate for fast-charging SIBs. In contrast, Nb2CO2 enhances charge retention through stronger electrostatic interactions but introduces higher migration resistance. Electronic structure analysis confirms the metallic nature of both MXenes, ensuring efficient electron transport. Open-circuit voltage (OCV) calculations indicate that Nb2CO2 exhibits higher OCV values than Nb2C, highlighting the role of surface functionalization in tuning electrochemical performance. Our study suggests that, while Li-based systems achieve slightly higher theoretical capacities, Na-based systems exhibit comparable performance, reinforcing the viability of sodium-ion batteries as a cost-effective alternative. Overall, our results demonstrate that Nb2C is better suited for rapid ion transport, whereas Nb2CO2 offers enhanced charge retention. These insights provide a foundation for the optimization of MXene-based electrodes for next-generation high performance energy storage applications.
title Insights into Nb2C and Nb2CO2 as high-performance anodes for sodium- and lithium-ion batteries: An ab initio investigation
topic Materials Science
url https://arxiv.org/abs/2504.08953