Energy gap at first-order quantum phase transitions: An anomalous case

Junichi Tsuda; Yuuki Yamanaka; Hidetoshi Nishimori

doi:10.7566/JPSJ.82.114004

Energy gap at first-order quantum phase transitions: An anomalous case

Junichi Tsuda, Yuuki Yamanaka, Hidetoshi Nishimori

INF - Applied Information Sciences

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

16 Citations (Scopus)

Abstract

We show that the rate of closing of the energy gap between the ground state and the first excited state, as a function of system size, behaves in many qualitatively different ways at first-order quantum phase transitions of the infiniterange quantum XY model. Examples include polynomial, exponential and even factorially-fast closing of the energy gap, all of which coexist along a single axis of the phase diagram representing the transverse field. This variety emerges depending on whether or not the transverse field assumes a rational number, as well as on how the series of system size is chosen toward the thermodynamic limit. We conclude that there is no generically applicable rule for relating the rate of gap closing to the order of quantum phase transitions as is often implied in many studies, particularly in relation to the computational complexity of quantum annealing in its implementation as quantum adiabatic computation.

Original language	English
Article number	114004
Journal	journal of the physical society of japan
Volume	82
Issue number	11
DOIs	https://doi.org/10.7566/JPSJ.82.114004
Publication status	Published - 2013 Nov

Keywords

Energy gap
Quantum annealing
Quantum phase transition

ASJC Scopus subject areas

Physics and Astronomy(all)

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N2 - We show that the rate of closing of the energy gap between the ground state and the first excited state, as a function of system size, behaves in many qualitatively different ways at first-order quantum phase transitions of the infiniterange quantum XY model. Examples include polynomial, exponential and even factorially-fast closing of the energy gap, all of which coexist along a single axis of the phase diagram representing the transverse field. This variety emerges depending on whether or not the transverse field assumes a rational number, as well as on how the series of system size is chosen toward the thermodynamic limit. We conclude that there is no generically applicable rule for relating the rate of gap closing to the order of quantum phase transitions as is often implied in many studies, particularly in relation to the computational complexity of quantum annealing in its implementation as quantum adiabatic computation.

AB - We show that the rate of closing of the energy gap between the ground state and the first excited state, as a function of system size, behaves in many qualitatively different ways at first-order quantum phase transitions of the infiniterange quantum XY model. Examples include polynomial, exponential and even factorially-fast closing of the energy gap, all of which coexist along a single axis of the phase diagram representing the transverse field. This variety emerges depending on whether or not the transverse field assumes a rational number, as well as on how the series of system size is chosen toward the thermodynamic limit. We conclude that there is no generically applicable rule for relating the rate of gap closing to the order of quantum phase transitions as is often implied in many studies, particularly in relation to the computational complexity of quantum annealing in its implementation as quantum adiabatic computation.

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Energy gap at first-order quantum phase transitions: An anomalous case

Abstract

Keywords

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