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Main Authors: Cugini, Davide, Guarnieri, Giacomo, Motta, Mario, Gerace, Dario
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2505.13717
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author Cugini, Davide
Guarnieri, Giacomo
Motta, Mario
Gerace, Dario
author_facet Cugini, Davide
Guarnieri, Giacomo
Motta, Mario
Gerace, Dario
contents Quantum state preparation lies at the heart of quantum computation and quantum simulations, enabling the investigation of complex manybody systems across physics, chemistry, and data science. While existing methods such as Variational Quantum Algorithms (VQAs) and Adiabatic Preparation (AP) offer viable pathways, both face substantial limitations. Here we introduce a hybrid algorithm that integrates the conceptual strengths of both VQAs and AP, enhanced via the use of group-theoretic structures and classical post-processing to approximate ground and excited states of many-body Hamiltonian models. We validate our approach by applying it to the one-dimensional XYZ Heisenberg model with periodic boundary conditions, evaluating its performance across a broad range of parameters and system sizes. Our results show accurate preparation of low-energy eigenstates, achieved with circuit depths with polynomial scaling versus system size.
format Preprint
id arxiv_https___arxiv_org_abs_2505_13717
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Symmetry-guided quantum state preparation: Branched-Subspaces Adiabatic Preparation (B-SAP)
Cugini, Davide
Guarnieri, Giacomo
Motta, Mario
Gerace, Dario
Quantum Physics
Quantum state preparation lies at the heart of quantum computation and quantum simulations, enabling the investigation of complex manybody systems across physics, chemistry, and data science. While existing methods such as Variational Quantum Algorithms (VQAs) and Adiabatic Preparation (AP) offer viable pathways, both face substantial limitations. Here we introduce a hybrid algorithm that integrates the conceptual strengths of both VQAs and AP, enhanced via the use of group-theoretic structures and classical post-processing to approximate ground and excited states of many-body Hamiltonian models. We validate our approach by applying it to the one-dimensional XYZ Heisenberg model with periodic boundary conditions, evaluating its performance across a broad range of parameters and system sizes. Our results show accurate preparation of low-energy eigenstates, achieved with circuit depths with polynomial scaling versus system size.
title Symmetry-guided quantum state preparation: Branched-Subspaces Adiabatic Preparation (B-SAP)
topic Quantum Physics
url https://arxiv.org/abs/2505.13717