Adiabatic quenches and characterization of amplitude excitations in a continuous quantum phase transition

Adiabatic quenches and characterization of amplitude excitations in a continuous quantum phase transition

Spontaneous symmetry breaking occurs in a physical system whenever the ground state does not share the symmetry of the underlying theory, e.g., the Hamiltonian. This mechanism gives rise to massless Nambu–Goldstone modes and massive Anderson–Higgs modes. These modes provide a fundamental understandi...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS Vol. 113; no. 34; pp. 9475 - 9479
Main Authors: Hoang, Thai M., Bharath, Hebbe M., Boguslawski, Matthew J., Anquez, Martin, Robbins, Bryce A., Chapman, Michael S.
Format: Journal Article
Language:English
Published: United States National Academy of Sciences 23-08-2016
Subjects:
Kinetics
Phase transitions
Physical Sciences
Quantum physics
Symmetry
quantum phase transition
adiabatic quenches
amplitude excitations
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Summary:Spontaneous symmetry breaking occurs in a physical system whenever the ground state does not share the symmetry of the underlying theory, e.g., the Hamiltonian. This mechanism gives rise to massless Nambu–Goldstone modes and massive Anderson–Higgs modes. These modes provide a fundamental understanding of matter in the Universe and appear as collective phase or amplitude excitations of an order parameter in a many-body system. The amplitude excitation plays a crucial role in determining the critical exponents governing universal nonequilibrium dynamics in the Kibble–Zurek mechanism (KZM). Here, we characterize the amplitude excitations in a spin-1 condensate and measure the energy gap for different phases of the quantum phase transition. At the quantum critical point of the transition, finite-size effects lead to a nonzero gap. Our measurements are consistent with this prediction, and furthermore, we demonstrate an adiabatic quench through the phase transition, which is forbidden at the mean field level. This work paves the way toward generating entanglement through an adiabatic phase transition.
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Edited by Subir Sachdev, Harvard University, Cambridge, MA, and approved June 28, 2016 (received for review January 7, 2016)
Author contributions: T.M.H. and M.S.C. designed research; T.M.H. performed research; T.M.H. analyzed data; T.M.H., H.M.B., M.J.B., M.A., B.A.R., and M.S.C. wrote the paper; M.S.C. conceived the study and supervised the research; T.M.H. conceived the study, developed essential theory, and carried out the simulations.; M.A. and B.A.R. assisted data taking; and H.M.B. and M.J.B. developed essential theory and carried out the simulations.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1600267113