Related papers: Truncated Gaussian basis approach for simulating many-body dynamics

Truncated Gaussian basis approach for simulating many-body dynamics

URL: http://arxiv.org/abs/2410.04204v1
Date: Sat, 5 Oct 2024 15:47:01 GMT
Title: Truncated Gaussian basis approach for simulating many-body dynamics
Authors: Nico Albert, Yueshui Zhang, Hong-Hao Tu,
Abstract summary: The approach constructs an effective Hamiltonian within a reduced subspace, spanned by fermionic Gaussian states, and diagonalizes it to obtain approximate eigenstates and eigenenergies. Symmetries can be exploited to perform parallel computation, enabling to simulate systems with much larger sizes. For quench dynamics we observe that time-evolving wave functions in the truncated subspace facilitates the simulation of long-time dynamics.
Score: 0.0
License: http://creativecommons.org/licenses/by/4.0/
Abstract: We propose a Truncated Gaussian Basis Approach (TGBA) for simulating the dynamics of quantum many-body systems. The approach constructs an effective Hamiltonian within a reduced subspace, spanned by fermionic Gaussian states, and diagonalizes it to obtain approximate eigenstates and eigenenergies. Symmetries can be exploited to perform parallel computation, enabling to simulate systems with much larger sizes. As an example, we compute the dynamic structure factor and study quench dynamics in a non-integrable quantum Ising chain, known as ``$E_8$ magnet''. The mass ratios calculated through the dynamic structure factor show excellent agreement with Zamolodchikov's analytical predictions. For quench dynamics we observe that time-evolving wave functions in the truncated subspace facilitates the simulation of long-time dynamics.

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