Continuous Phase Transition without Gap Closing in Non-Hermitian Quantum Many-Body Systems
Norifumi Matsumoto, Kohei Kawabata, Yuto Ashida, Shunsuke Furukawa, Masahito Ueda
Abstract
Contrary to the conventional wisdom in Hermitian systems, a continuous quantum phase transition between gapped phases is shown to occur without closing the energy gap $\mathrm{\ensuremath{\Delta}}$ in non-Hermitian quantum many-body systems. Here, the relevant length scale $\ensuremath{\xi}\ensuremath{\simeq}{v}_{\mathrm{LR}}/\mathrm{\ensuremath{\Delta}}$ diverges because of the breakdown of the Lieb-Robinson bound on the velocity (i.e., unboundedness of ${v}_{\mathrm{LR}}$) rather than vanishing of the energy gap $\mathrm{\ensuremath{\Delta}}$. The susceptibility to a change in the system parameter exhibits a singularity due to nonorthogonality of eigenstates. As an illustrative example, we present an exactly solvable model by generalizing Kitaev's toric-code model to a non-Hermitian regime.