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Dissecting van der Waals interactions with Density Functional Theory - Wannier-basis approach
arXiv
Authors: Diem Thi-Xuan Dang, Dai-Nam Le, Lilia M. Woods
Year
2024
Paper ID
66435
Status
Preprint
Abstract Read
~2 min
Abstract Words
135
Citations
N/A
Abstract
A new scheme for the computation of dispersive interactions from first principles is presented. This cost-effective approach relies on a Wannier function representation compatible with density function theory descriptions. This is an electronic-based many-body method that captures the full electronic and optical response properties of the materials. It provides the foundation to discern van der Waals and induction energies as well as the role of anisotropy and different stacking patterns when computing dispersive interactions in systems. Calculated results for binding energies in benchmarked materials and layered materials, such as graphite, hBN, and MoS2 give encouraging comparisons with available experimental data. Strategies for broadened computational descriptions of dispersive interactions are also discussed. Our investigation aims at stimulating new experimental studies to measure van der Waals energies in a wider range of materials, especially in layered systems.
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- This paper contributes to the Quantum Foundations research area in the Quantum Articles archive.
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- A new scheme for the computation of dispersive interactions from first principles is presented.
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