Excited-state quantum phase transitions in systems with two degrees of freedom: II. Finite-size effects

Pavel Stránský; Michal Macek; Amiram Leviatan; Pavel Cejnar

doi:10.1016/j.aop.2015.02.025

Excited-state quantum phase transitions in systems with two degrees of freedom: II. Finite-size effects

Pavel Stránský, Michal Macek, Amiram Leviatan, Pavel Cejnar

Racah Institute of Physics

The Hebrew University of Jerusalem

Research output: Contribution to journal › Article › peer-review

Abstract

This article extends our previous analysis Stránský etal. (2014) of Excited-State Quantum Phase Transitions (ESQPTs) in systems of dimension two. We focus on the oscillatory component of the quantum state density in connection with ESQPT structures accompanying a first-order ground-state transition. It is shown that a separable (integrable) system can develop rather strong finite-size precursors of ESQPT expressed as singularities in the oscillatory component of the state density. The singularities originate in effectively 1-dimensional dynamics and in some cases appear in multiple replicas with increasing excitation energy. Using a specific model example, we demonstrate that these precursors are rather resistant to proliferation of chaotic dynamics.

Original language	English
Pages (from-to)	57-82
Number of pages	26
Journal	Annals of Physics
Volume	356
DOIs	https://doi.org/10.1016/j.aop.2015.02.025
State	Published - 1 May 2015

Keywords

Finite-size effects
Oscillatory component of level density
Quantum phase transitions
Regular/chaotic dynamics

All Science Journal Classification (ASJC) codes

General Physics and Astronomy

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10.1016/j.aop.2015.02.025

Cite this

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title = "Excited-state quantum phase transitions in systems with two degrees of freedom: II. Finite-size effects",

abstract = "This article extends our previous analysis Str{\'a}nsk{\'y} etal. (2014) of Excited-State Quantum Phase Transitions (ESQPTs) in systems of dimension two. We focus on the oscillatory component of the quantum state density in connection with ESQPT structures accompanying a first-order ground-state transition. It is shown that a separable (integrable) system can develop rather strong finite-size precursors of ESQPT expressed as singularities in the oscillatory component of the state density. The singularities originate in effectively 1-dimensional dynamics and in some cases appear in multiple replicas with increasing excitation energy. Using a specific model example, we demonstrate that these precursors are rather resistant to proliferation of chaotic dynamics.",

keywords = "Finite-size effects, Oscillatory component of level density, Quantum phase transitions, Regular/chaotic dynamics",

author = "Pavel Str{\'a}nsk{\'y} and Michal Macek and Amiram Leviatan and Pavel Cejnar",

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doi = "10.1016/j.aop.2015.02.025",

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AU - Macek, Michal

AU - Leviatan, Amiram

AU - Cejnar, Pavel

PY - 2015/5/1

Y1 - 2015/5/1

N2 - This article extends our previous analysis Stránský etal. (2014) of Excited-State Quantum Phase Transitions (ESQPTs) in systems of dimension two. We focus on the oscillatory component of the quantum state density in connection with ESQPT structures accompanying a first-order ground-state transition. It is shown that a separable (integrable) system can develop rather strong finite-size precursors of ESQPT expressed as singularities in the oscillatory component of the state density. The singularities originate in effectively 1-dimensional dynamics and in some cases appear in multiple replicas with increasing excitation energy. Using a specific model example, we demonstrate that these precursors are rather resistant to proliferation of chaotic dynamics.

AB - This article extends our previous analysis Stránský etal. (2014) of Excited-State Quantum Phase Transitions (ESQPTs) in systems of dimension two. We focus on the oscillatory component of the quantum state density in connection with ESQPT structures accompanying a first-order ground-state transition. It is shown that a separable (integrable) system can develop rather strong finite-size precursors of ESQPT expressed as singularities in the oscillatory component of the state density. The singularities originate in effectively 1-dimensional dynamics and in some cases appear in multiple replicas with increasing excitation energy. Using a specific model example, we demonstrate that these precursors are rather resistant to proliferation of chaotic dynamics.

KW - Finite-size effects

KW - Oscillatory component of level density

KW - Quantum phase transitions

KW - Regular/chaotic dynamics

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DO - 10.1016/j.aop.2015.02.025

M3 - مقالة

SN - 0003-4916

VL - 356

SP - 57

EP - 82

JO - Annals of Physics

JF - Annals of Physics

ER -

Excited-state quantum phase transitions in systems with two degrees of freedom: II. Finite-size effects

Abstract

Keywords

All Science Journal Classification (ASJC) codes

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