Intermittency of dynamical phases in a quantum spin glass

Abstract

Answering the question of existence of efficient quantum algorithms for NP-hard problems require deep theoretical understanding of the properties of the low-energy eigenstates and long-time coherent dynamics in quantum spin glasses. We discovered and described analytically the property of asymptotic orthogonality resulting in a new type of structure in quantum spin glass. Its eigen-spectrum is split into the alternating sequence of bands formed by quantum states of two distinct types (x and z). Those of z-type are non-ergodic extended eigenstates (NEE) in the basis of \σz\ operators that inherit the structure of the classical spin glass with exponentially long decay times of Edwards Anderson order parameter at any finite value of transverse field B. Those of x-type form narrow bands of NEEs that conserve the integer-valued x-magnetization. Quantum evolution within a given band of each type is described by a Hamiltonian that belongs to either the ensemble of Preferred Basis Levi matrices (z-type) or Gaussian Orthogonal ensemble (x-type). We characterize the non-equilibrium dynamics using fractal dimension D that depends on energy density (temperature) and plays a role of thermodynamic potential: D=0 in MBL phase, 0<D<1 in NEE phase, D→ 1 in ergodic phase in infinite temperature limit. MBL states coexist with NEEs in the same range of energies even at very large B. Bands of NEE states can be used for new quantum search-like algorithms of population transfer in the low-energy part of spin-configuration space. Remarkably, the intermitted structure of the eigenspectrum emerges in quantum version of a statistically featureless Random Energy Model and is expected to exist in a class of paractically important NP-hard problems that unlike REM can be implemented on a computer with polynomial resources.