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Main Authors: Moghadas, Emin, Dräger, Nikolaus, Toschi, Alessandro, Zang, Jiawei, Medvidović, Matija, Kiese, Dominik, Millis, Andrew J., Sengupta, Anirvan M., Andergassen, Sabine, Di Sante, Domenico
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2402.13030
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author Moghadas, Emin
Dräger, Nikolaus
Toschi, Alessandro
Zang, Jiawei
Medvidović, Matija
Kiese, Dominik
Millis, Andrew J.
Sengupta, Anirvan M.
Andergassen, Sabine
Di Sante, Domenico
author_facet Moghadas, Emin
Dräger, Nikolaus
Toschi, Alessandro
Zang, Jiawei
Medvidović, Matija
Kiese, Dominik
Millis, Andrew J.
Sengupta, Anirvan M.
Andergassen, Sabine
Di Sante, Domenico
contents Precise algorithms capable of providing controlled solutions in the presence of strong interactions are transforming the landscape of quantum many-body physics. Particularly exciting breakthroughs are enabling the computation of non-zero temperature correlation functions. However, computational challenges arise due to constraints in resources and memory limitations, especially in scenarios involving complex Green's functions and lattice effects. Leveraging the principles of signal processing and data compression, this paper explores the wavelet decomposition as a versatile and efficient method for obtaining compact and resource-efficient representations of the many-body theory of interacting systems. The effectiveness of the wavelet decomposition is illustrated through its application to the representation of generalized susceptibilities and self-energies in a prototypical interacting fermionic system, namely the Hubbard model at half-filling in its atomic limit. These results are the first proof-of-principle application of the wavelet compression within the realm of many-body physics and demonstrate the potential of this wavelet-based compression scheme for understanding the physics of correlated electron systems.
format Preprint
id arxiv_https___arxiv_org_abs_2402_13030
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Compressing the two-particle Green's function using wavelets: Theory and application to the Hubbard atom
Moghadas, Emin
Dräger, Nikolaus
Toschi, Alessandro
Zang, Jiawei
Medvidović, Matija
Kiese, Dominik
Millis, Andrew J.
Sengupta, Anirvan M.
Andergassen, Sabine
Di Sante, Domenico
Strongly Correlated Electrons
Precise algorithms capable of providing controlled solutions in the presence of strong interactions are transforming the landscape of quantum many-body physics. Particularly exciting breakthroughs are enabling the computation of non-zero temperature correlation functions. However, computational challenges arise due to constraints in resources and memory limitations, especially in scenarios involving complex Green's functions and lattice effects. Leveraging the principles of signal processing and data compression, this paper explores the wavelet decomposition as a versatile and efficient method for obtaining compact and resource-efficient representations of the many-body theory of interacting systems. The effectiveness of the wavelet decomposition is illustrated through its application to the representation of generalized susceptibilities and self-energies in a prototypical interacting fermionic system, namely the Hubbard model at half-filling in its atomic limit. These results are the first proof-of-principle application of the wavelet compression within the realm of many-body physics and demonstrate the potential of this wavelet-based compression scheme for understanding the physics of correlated electron systems.
title Compressing the two-particle Green's function using wavelets: Theory and application to the Hubbard atom
topic Strongly Correlated Electrons
url https://arxiv.org/abs/2402.13030