First-principles study of two-dimensional C-silicyne nanosheet as a promising anode material for rechargeable Li-ion batteries

Li-ion batteries are one of the sustainable alternatives to meet the growing energy demands of an increasing population. However, finding a suitable negative electrode is key for improving battery performance. In the present work, first principles-based investigations are carried out to explore the...

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Published inPhysical chemistry chemical physics : PCCP Vol. 24; no. 34; pp. 2274 - 2281
Main Authors Duhan, Nidhi, Dhilip Kumar, T. J
Format Journal Article
LanguageEnglish
Published Cambridge Royal Society of Chemistry 31.08.2022
Subjects
Adsorption
Alternative energy sources
Anodes
Clustering
Electrode materials
First principles
Lithium-ion batteries
Metal sheets
Monolayers
Nanosheets
Rechargeable batteries
Silicon
Storage capacity
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Summary:Li-ion batteries are one of the sustainable alternatives to meet the growing energy demands of an increasing population. However, finding a suitable negative electrode is key for improving battery performance. In the present work, first principles-based investigations are carried out to explore the capability of a planar 2D C-silicyne nanosheet - which is a Si analogue of α-graphyne having -C&z.tbd;C- substitution - as an anode for improving the performance of Li-ion batteries. Thermally and dynamically stable C-silicyne sheets exhibit a metallic nature as inferred from the density of states studies. The average adsorption energies for sequential adsorption of the Li atom over the monolayer range from −1.35 to −0.46 eV, implying favourable interactions between the monolayer and the Li atom which indicate that during the lithiation process, clustering amongst the metal atoms is not preferred. The energy barrier for the migration of Li-ions is 0.21 eV, indicating an active charge/discharge process. A high storage capacity of 836.07 mA h g −1 and a working potential of 0.60 V is obtained. A negligible amount of volume change of the C-silicyne monolayer after full lithiation is observed which implies good cyclability. All these outcomes imply that C-silicyne nanosheets are a potential anode material for next-generation LIBs. First principles-based investigations are carried out to explore the capability of a planar 2D C-silicyne nanosheet as an anode for improving the performance of Li-ion batteries.
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Electronic supplementary information (ESI) available: (1) Coordinates for C-silicyne unit cell, (2) information and structures during systematic loading of Li atoms over the monolayer, (3) formula to calculate formation energy, (4) calculation of Li coverage ratio, (5) energy profile for diffusion path B with structures, (6) side view of the nanosheet representing the adsorption distance
plane of the C-silicyne nanosheet as a function of Li loading. See DOI
https://doi.org/10.1039/d2cp02560d
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ISSN:1463-9076
1463-9084
DOI:10.1039/d2cp02560d