Driven-Dissipative Phase Transition in a Kerr Oscillator: From Semi-Classical PT Symmetry to Quantum Fluctuations.
Abstract
We study a minimal model that has a driven-dissipative quantum phase
transition, namely a Kerr non-linear oscillator subject to driving and
dissipation. Using mean-field theory, exact diagonalization, and the Keldysh formalism,
we analyze the critical phenomena in this system, showing which aspects can be captured
by each approach and how the approaches complement each other. Then critical scaling
and finite-size scaling are calculated analytically using the quantum Langevin equation.
The physics contained in this simple model is surprisingly rich: it includes a continuous
phase transition, Z2 symmetry breaking, PT symmetry, state squeezing, and critical
fluctuations. Due to its simplicity and solvability, this model can serve as a paradigm
for exploration of open quantum many-body physics.
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https://hdl.handle.net/10161/26448Published Version (Please cite this version)
10.1103/PhysRevA.103.033711Publication Info
(2021). Driven-Dissipative Phase Transition in a Kerr Oscillator: From Semi-Classical PT Symmetry
to Quantum Fluctuations. Physical Review A, 103(3). pp. 033711-033711. 10.1103/PhysRevA.103.033711. Retrieved from https://hdl.handle.net/10161/26448.This is constructed from limited available data and may be imprecise. To cite this
article, please review & use the official citation provided by the journal.
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Show full item recordScholars@Duke
Harold U. Baranger
Professor of Physics
The broad focus of Prof. Baranger's group is quantum open systems at the nanoscale,
particularly the generation of correlation between particles in such systems. Fundamental
interest in nanophysics-- the physics of small, nanometer scale, bits of solid-- stems
from the ability to control and probe systems on length scales larger than atoms but
small enough that the averaging inherent in bulk properties has not yet occurred.
Using this ability, entirely unanticipated phenomena ca
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