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Bibliographic Details
Main Author: Elfakir, Jamal
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2605.00241
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author Elfakir, Jamal
author_facet Elfakir, Jamal
contents This thesis, explores the quantum entanglement and evolution through both a geometric and dynamical perspective. The first part focuses on classical phase space and its central role in Hamiltonian mechanics, emphasizing the importance of symplectic structures in describing mechanical states. The study highlights the formal analogy between classical phase space and the Hilbert space used in quantum mechanics. The second part is devoted to the geometric description of quantum states through the projective structure of Hilbert space. Emphasis is placed on the geometric interpretation of quantum evolution, particularly via the Fubini-Study metric, associated symplectic structures, and the geometric phase acquired during unitary evolutions. The final two parts are dedicated to the study of spin systems (both two-body and many-body) under different interaction models (XXZ Heisenberg and all-range Ising). Both the dynamical aspects (evolution speed, entanglement, and the quantum brachistochrone problem) and the geometric and topological structures of the corresponding quantum states are analyzed.
format Preprint
id arxiv_https___arxiv_org_abs_2605_00241
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Exploring the Geometric and Dynamical Properties of Spin Systems and Their Interplay with Quantum Entanglement
Elfakir, Jamal
Quantum Physics
This thesis, explores the quantum entanglement and evolution through both a geometric and dynamical perspective. The first part focuses on classical phase space and its central role in Hamiltonian mechanics, emphasizing the importance of symplectic structures in describing mechanical states. The study highlights the formal analogy between classical phase space and the Hilbert space used in quantum mechanics. The second part is devoted to the geometric description of quantum states through the projective structure of Hilbert space. Emphasis is placed on the geometric interpretation of quantum evolution, particularly via the Fubini-Study metric, associated symplectic structures, and the geometric phase acquired during unitary evolutions. The final two parts are dedicated to the study of spin systems (both two-body and many-body) under different interaction models (XXZ Heisenberg and all-range Ising). Both the dynamical aspects (evolution speed, entanglement, and the quantum brachistochrone problem) and the geometric and topological structures of the corresponding quantum states are analyzed.
title Exploring the Geometric and Dynamical Properties of Spin Systems and Their Interplay with Quantum Entanglement
topic Quantum Physics
url https://arxiv.org/abs/2605.00241