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Measurement-Induced Dark State Phase Transitions in Long-Ranged Fermion Systems

T. Müller, S. Diehl, M. Buchhold

2022Physical Review Letters165 citationsDOIOpen Access PDF

Abstract

We identify an unconventional algebraic scaling phase in the quantum dynamics of long-range hopping, free fermions, which are exposed to continuous local measurements. The algebraic phase occurs for hopping decay exponents 1<p≲3/2, and features an algebraic entanglement entropy growth, and a slow algebraic decay of the density-density correlation function, both with a fractional exponent. It is separated from a critical phase with logarithmic entanglement growth at small, and an area law phase with constant entanglement entropy at large monitoring rates. A perturbative renormalization group analysis predicts that the transitions to the long-range phase correspond to an unconventional, modified sine-Gordon theory. Exact numerical simulations of the monitored wave functions are in excellent agreement with an analytical replica field theory approach, which confirms the view of the measurement-induced phase transition as a quantum phase transition in the dark state of an effective, non-Hermitian Hamiltonian.

Topics & Concepts

PhysicsQuantum entanglementQuantum phase transitionRenormalization groupCritical exponentQuantum mechanicsPhase transitionLogarithmScalingAlgebraic numberEntropy (arrow of time)RenormalizationFermionCritical phenomenaStatistical physicsPhase (matter)Quantum metrologyQuantum field theoryQuantumQuantum electrodynamicsFunctional renormalization groupCritical dimensionQuantum critical pointCondensed matter physicsMathematical physicsQuantum discordDark stateReplicaSquashed entanglementUniversality (dynamical systems)Logarithmic growthField (mathematics)Quantum many-body systemsQuantum Mechanics and Non-Hermitian PhysicsQuantum Information and Cryptography
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