Related papers: Generating and analyzing small-size datasets to explore physical observables in quantum Ising systems

Generating and analyzing small-size datasets to explore physical observables in quantum Ising systems

URL: http://arxiv.org/abs/2411.07701v1
Date: Tue, 12 Nov 2024 10:31:09 GMT
Title: Generating and analyzing small-size datasets to explore physical observables in quantum Ising systems
Authors: Rodrigo Carmo Terin,
Abstract summary: We propose a detailed analysis of datasets generated from simulations of two-dimensional quantum spin systems. Our focus is on examining how fundamental physical properties, energy, magnetization, and entanglement entropy evolve under varying external transverse magnetic fields and system sizes.
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Abstract: We propose a detailed analysis of datasets generated from simulations of two-dimensional quantum spin systems using the quantum Ising model at absolute zero temperature. Our focus is on examining how fundamental physical properties, energy, magnetization, and entanglement entropy, evolve under varying external transverse magnetic fields and system sizes. From the Quantum Toolbox in Python (QuTiP), we simulate systems with 4, 8, and 16 spins arranged in square lattices, generating extensive datasets with 5000 samples per magnetic field value. The Hamiltonian operator incorporates quantum mechanical effects such as superposition and tunneling, challenging classical interpretations of spin states. We compute extended Pauli operators and construct the Hamiltonian to include spin-spin interactions and transverse field terms. Our analysis reveals that as the system size increases, fluctuations in energy and entanglement entropy become more evident, indicating lifted sensitivity to external perturbations and suggesting the onset of quantum phase transitions. Spin-spin correlation functions demonstrate that interactions are predominantly local, but larger systems exhibit more complex and fluctuating correlations. These findings provide valuable insights into the behavior of quantum spin systems and lay the groundwork for future machine learning applications aimed at predicting physical quantities and identifying phase transitions from a quantum perspective.

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