Related papers: Simulating matrix models with tensor networks

Simulating matrix models with tensor networks

URL: http://arxiv.org/abs/2412.04133v1
Date: Thu, 05 Dec 2024 12:57:58 GMT
Title: Simulating matrix models with tensor networks
Authors: Enrico M. Brehm, Yibin Guo, Karl Jansen, Enrico Rinaldi,
Abstract summary: Matrix models, as quantum mechanical systems without explicit spatial dependence, provide valuable insights into gauge and gravitational theories.<n>Simulating these models allows for exploration of their kinematic and dynamic properties.<n>We construct ground states as matrix product states and analyse features such as their entanglement structure.
Score: 0.0
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Matrix models, as quantum mechanical systems without explicit spatial dependence, provide valuable insights into higher-dimensional gauge and gravitational theories, especially within the framework of string theory, where they can describe quantum black holes via the holographic principle. Simulating these models allows for exploration of their kinematic and dynamic properties, particularly in parameter regimes that are analytically intractable. In this study, we examine the potential of tensor network techniques for such simulations. Specifically, we construct ground states as matrix product states and analyse features such as their entanglement structure.

Related papers

Geometric Principles for Machine Learning of Dynamical Systems [0.0]
This paper proposes leveraging structure-rich geometric spaces for machine learning to achieve structural generalization. We illustrate this view through the machine learning of linear time-invariant dynamical systems.
arXiv Detail & Related papers (2025-02-19T17:28:40Z)
Exact Model Reduction for Continuous-Time Open Quantum Dynamics [0.0]
We consider finite-dimensional many-body quantum systems described by time-independent Hamiltonians and Markovian master equations. We present a systematic method for constructing smaller-dimensional, reduced models that reproduce the time evolution of a set of initial conditions or observables of interest.
arXiv Detail & Related papers (2024-12-06T15:00:58Z)
Truncated Gaussian basis approach for simulating many-body dynamics [0.0]
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.
arXiv Detail & Related papers (2024-10-05T15:47:01Z)
Quantum Simulation of Nonlinear Dynamical Systems Using Repeated Measurement [42.896772730859645]
We present a quantum algorithm based on repeated measurement to solve initial-value problems for nonlinear ordinary differential equations. We apply this approach to the classic logistic and Lorenz systems in both integrable and chaotic regimes.
arXiv Detail & Related papers (2024-10-04T18:06:12Z)
Topological Eigenvalue Theorems for Tensor Analysis in Multi-Modal Data Fusion [0.0]
This paper presents a novel framework for tensor eigenvalue analysis in the context of multi-modal data fusion. By establishing new theorems that link eigenvalues to topological features, the proposed framework provides deeper insights into the latent structure of data.
arXiv Detail & Related papers (2024-09-14T09:46:15Z)
Hamiltonian truncation tensor networks for quantum field theories [42.2225785045544]
We introduce a tensor network method for the classical simulation of continuous quantum field theories. The method is built on Hamiltonian truncation and tensor network techniques. One of the key developments is the exact construction of matrix product state representations of global projectors.
arXiv Detail & Related papers (2023-12-19T19:00:02Z)
Eigenvalue analysis of three-state quantum walks with general coin matrices [0.7343478057671141]
We develop a more sophisticated transfer matrix framework applicable to three-state quantum walks with general coin matrices. We perform numerical analyses to derive exact eigenvalues for models that were previously considered intractable.
arXiv Detail & Related papers (2023-11-11T03:37:24Z)
Revisiting semiconductor bulk hamiltonians using quantum computers [0.0]
We use k$cdot$p Hamiltonians to describe semiconductor structures of the III-V family. We obtain their band structures using a state vector solver, a probabilistic simulator, and a real noisy-device simulator.
arXiv Detail & Related papers (2022-08-22T14:02:29Z)
Symmetry Group Equivariant Architectures for Physics [52.784926970374556]
In the domain of machine learning, an awareness of symmetries has driven impressive performance breakthroughs. We argue that both the physics community and the broader machine learning community have much to understand.
arXiv Detail & Related papers (2022-03-11T18:27:04Z)
Characterizing the dynamical phase diagram of the Dicke model via classical and quantum probes [0.0]
We study the dynamical phase diagram of the Dicke model in both classical and quantum limits. Our numerical calculations demonstrate that mean-field features of the dynamics remain valid in the exact quantum dynamics. Our predictions can be verified in current quantum simulators of the Dicke model including arrays of trapped ions.
arXiv Detail & Related papers (2021-02-03T19:05:56Z)
State preparation and measurement in a quantum simulation of the O(3) sigma model [65.01359242860215]
We show that fixed points of the non-linear O(3) sigma model can be reproduced near a quantum phase transition of a spin model with just two qubits per lattice site. We apply Trotter methods to obtain results for the complexity of adiabatic ground state preparation in both the weak-coupling and quantum-critical regimes. We present and analyze a quantum algorithm based on non-unitary randomized simulation methods.
arXiv Detail & Related papers (2020-06-28T23:44:12Z)
Lorentz Group Equivariant Neural Network for Particle Physics [58.56031187968692]
We present a neural network architecture that is fully equivariant with respect to transformations under the Lorentz group. For classification tasks in particle physics, we demonstrate that such an equivariant architecture leads to drastically simpler models that have relatively few learnable parameters.
arXiv Detail & Related papers (2020-06-08T17:54:43Z)
Tensor network models of AdS/qCFT [69.6561021616688]
We introduce the notion of a quasiperiodic conformal field theory (qCFT) We show that qCFT can be best understood as belonging to a paradigm of discrete holography.
arXiv Detail & Related papers (2020-04-08T18:00:05Z)

This list is automatically generated from the titles and abstracts of the papers in this site.