Anisotropic van der Waals Dispersion Forces in Polymers: Structural Symmetry Breaking Leads to Enhanced Conformational Search

Galante, Mario; Tkatchenko, Alexandre

doi:10.48550/arxiv.2110.06646

Cited by 2 publications

(2 citation statements)

References 27 publications

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“…Noncovalent interactions [1][2][3][4] play a key role in determining physicochemical properties, given that they influence the structure [5], stability [6,7], dynamics [8][9][10], and electric [11] and optical [12] responses in a wide range of molecules and materials [13][14][15]. In particular, van der Waals (vdW) dispersion interactions and long-range electron correlation energy must be treated with quantitative many-body methods [16][17][18][19][20][21][22][23][24].…”

mentioning

confidence: 99%

Second Quantization Approach to Many-Body Dispersion Interactions: Implications for Chemical and Biological Systems

Tkatchenko

Gori

Kurian

2023

Preprint

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The many-body dispersion (MBD) framework is a successful approach for modeling the long- range electronic correlation energy and optical response of systems with thousands of atoms. Inspired by field theory, here we develop a second-quantized MBD formalism (SQ-MBD) that recasts a system of atomic quantum Drude oscillators in a Fock-space representation. SQ-MBD provides: (i) tools for projecting observables (interaction energy, transition multipoles, polarizability tensors) on coarse-grained representations of the atomistic system ranging from single atoms to large structural motifs, (ii) a quantum-information framework to analyze correlations and (non)separability among fragments in a given molecular complex, and (iii) a path toward the applicability of the MBD framework to molecular complexes with millions of atoms. The SQ-MBD approach offers novel insights into quantum fluctuations in molecular systems and enables direct coupling of collective plasmon-like MBD degrees of freedom with arbitrary environments, providing a tractable computational framework to treat dispersion interactions and polarization response in intricate systems.

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confidence: 99%

Second Quantization Approach to Many-Body Dispersion Interactions: Implications for Chemical and Biological Systems

Tkatchenko

Gori

Kurian

2023

Preprint

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confidence: 99%

Second Quantization Approach to Many-Body Dispersion Interactions

Gori¹,

Kurian²,

Tkatchenko³

2022

Preprint

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The many-body dispersion (MBD) framework is a successful approach for modeling the long-range electronic correlation energy and optical response of systems with thousands of atoms. Inspired by field theory, here we develop a second-quantized MBD formalism (SQ-MBD) that recasts a system of atomic quantum Drude oscillators in a Fock-space representation. SQ-MBD provides: (i) tools for projecting observables (interaction energy, transition multipoles, polarizability tensors) on coarse-grained representations of the atomistic system ranging from single atoms to large structural motifs, (ii) a quantum-information framework to analyze correlations and (non)separability among fragments in a given molecular complex, and (iii) a path toward the applicability of the MBD framework to molecular complexes with millions of atoms. The SQ-MBD approach offers novel insights into quantum fluctuations in molecular systems and enables direct coupling of collective plasmonlike MBD degrees of freedom with arbitrary environments, providing a tractable computational framework to treat dispersion interactions and polarization response in intricate systems.

show abstract

Anisotropic van der Waals Dispersion Forces in Polymers: Structural Symmetry Breaking Leads to Enhanced Conformational Search

Cited by 2 publications

References 27 publications

Second Quantization Approach to Many-Body Dispersion Interactions: Implications for Chemical and Biological Systems

Second Quantization Approach to Many-Body Dispersion Interactions: Implications for Chemical and Biological Systems

Second Quantization Approach to Many-Body Dispersion Interactions

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