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Emergence of multiple Higgs modes due to spontaneous breakdown of a $mathbb{Z}_2$ symmetry in a superconductor

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 Added by Shunji Tsuchiya
 Publication date 2021
  fields Physics
and research's language is English




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We study the Higgs mode in a Bardeen-Cooper-Schrieffer (BCS) superconductor. Motivated by the observation that U(1) symmetry of the BCS Hamiltonian is not essential for the Higgs mode, we study the Ising-like Hamiltonian in the pseudospin representation. We show that the Higgs mode emerges as the lowest excited state of the Ising-like Hamiltonian due to spontaneous breakdown of $mathbb{Z}_2$ symmetry under the time-reversal operation $mathcal T$ in the pseudospin space. We further predict the existence of multiple Higgs modes that have quantized energy $2(n+1)Delta_0$ ($0le nle N_{k_F}$), where $Delta_0$ is the superconducting gap, $n$ is an integer, and $N_{k_F}$ is the number of states on the Fermi surface.



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We study the quench dynamics of a topological $p$-wave superfluid with two competing order parameters, $Delta_pm(t)$. When the system is prepared in the $p+ip$ ground state and the interaction strength is quenched, only $Delta_+(t)$ is nonzero. However, we show that fluctuations in the initial conditions result in the growth of $Delta_-(t)$ and chaotic oscillations of both order parameters. We term this behavior phase III. In addition, there are two other types of late time dynamics -- phase I where both order parameters decay to zero and phase II where $Delta_+(t)$ asymptotes to a nonzero constant while $Delta_-(t)$ oscillates near zero. Although the model is nonintegrable, we are able to map out the exact phase boundaries in parameter space. Interestingly, we find phase III is unstable with respect to breaking the time reversal symmetry of the interaction. When one of the order parameters is favored in the Hamiltonian, the other one rapidly vanishes and the previously chaotic phase III is replaced by the Floquet topological phase III that is seen in the integrable chiral $p$-wave model.
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