Measurement-induced entanglement transitions in many-body localized systems

Lunt, Oliver; Pal, Arijeet

doi:10.1103/physrevresearch.2.043072

Cited by 89 publications

(37 citation statements)

References 66 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…These measurement-induced transitions occur in a wide variety of models, including random circuits , Hamiltonian systems [36][37][38][39][40][41][42][43][44], and measurement-only models [28,45,46,57], and they exhibit universal behavior. However, the determination of the relevant universality classes has proved to be a subtle issue.…”

Section: Introductionmentioning

confidence: 99%

Measurement-induced criticality and entanglement clusters: A study of one-dimensional and two-dimensional Clifford circuits

2021

Self Cite

View full text Add to dashboard Cite

Entanglement transitions in quantum dynamics present a novel class of phase transitions in nonequilibrium systems. When a many-body quantum system undergoes unitary evolution interspersed with monitored random measurements, the steady state can exhibit a phase transition between volume-and area-law entanglement. There is a correspondence between measurement-induced transitions in nonunitary quantum circuits in d spatial dimensions and classical statistical mechanical models in d + 1 dimensions. In certain limits these models map to percolation, but there is analytical and numerical evidence to suggest that away from these limits the universality class should generically be distinct from percolation. Intriguingly, despite these arguments, numerics on 1 + 1D qubit circuits give bulk exponents which are nonetheless close to those of 2D percolation, with some possible differences in surface behavior. In the first part of this work we explore the critical properties of 2 + 1D Clifford circuits. In the bulk, we find many properties suggested by the percolation picture, including several matching bulk exponents, and an inverse power law for the critical entanglement growth, S(t, L) ∼ L(1 − a/t ), which saturates to an area law. We then utilize a graph-state-based algorithm to analyze in 1 + 1D and 2 + 1D the critical properties of entanglement clusters in the steady state. We show that in a model with a simple geometric map to percolation-the projective transverse field Ising model-these entanglement clusters are governed by percolation surface exponents. However, in the Clifford models we find large deviations in the cluster exponents from those of surface percolation, highlighting the breakdown of any possible geometric map to percolation. Given the evidence for deviations from the percolation universality class, our results raise the question of why nonetheless many bulk properties behave similarly to those of percolation.

show abstract

Section: Introductionmentioning

confidence: 99%

Measurement-induced criticality and entanglement clusters: A study of one-dimensional and two-dimensional Clifford circuits

2021

Self Cite

View full text Add to dashboard Cite

show abstract

“…The entanglement transitions were firstly described in quantum circuits with projective measurements [37,38,43] and arise due to the competition between unitary dynamics, that tends to increase the entanglement, and local measurements, which suppress the long-range entanglement in the system. Entanglement transitions were found also in many-body systems undergoing Hamiltonian evolution with random measurements [123,[126][127][128]. From the perspective of protection of quantum information against the non-unitary evolution of the system, the volume-law phase can be identified as a quantum error-correcting phase in which initially mixed state gets purified at time scale exponential in system size, whereas in the area-law phase the purification time is system size independent [46].…”

Section: Entanglement Transitionmentioning

confidence: 99%

Dissipative Floquet Dynamics: from Steady State to Measurement Induced Criticality in Trapped-ion Chains

Sierant

Chiriacò

Surace

et al. 2022

Quantum

View full text Add to dashboard Cite

Quantum systems evolving unitarily and subject to quantum measurements exhibit various types of non-equilibrium phase transitions, arising from the competition between unitary evolution and measurements. Dissipative phase transitions in steady states of time-independent Liouvillians and measurement induced phase transitions at the level of quantum trajectories are two primary examples of such transitions. Investigating a many-body spin system subject to periodic resetting measurements, we argue that many-body dissipative Floquet dynamics provides a natural framework to analyze both types of transitions. We show that a dissipative phase transition between a ferromagnetic ordered phase and a paramagnetic disordered phase emerges for long-range systems as a function of measurement probabilities. A measurement induced transition of the entanglement entropy between volume law scaling and sub-volume law scaling is also present, and is distinct from the ordering transition. The two phases correspond to an error-correcting and a quantum-Zeno regimes, respectively. The ferromagnetic phase is lost for short range interactions, while the volume law phase of the entanglement is enhanced. An analysis of multifractal properties of wave function in Hilbert space provides a common perspective on both types of transitions in the system. Our findings are immediately relevant to trapped ion experiments, for which we detail a blueprint proposal based on currently available platforms.

show abstract

“…( 30) with finite N = 30 and η 0 = 1; the dashed lines correspond to the analytical result from Eq. (45). The predominant feature is an emerging gap in the imaginary part of the eigenvalues corresponding to the measurementinduced mass.…”

Section: Riccati Spectrum and Relaxationmentioning

confidence: 99%

“…It has a modified dispersion h(q) → ε(q), displayed in Eq. (45). To probe how physical this spectral information is we attempt the ansatz…”

Section: Correlation Functions and Entanglementmentioning

confidence: 99%

Continuous gaussian measurements of the free boson CFT: A model for exactly solvable and detectable measurement-induced dynamics

2022

View full text Add to dashboard Cite

Hybrid evolution protocols, composed of unitary dynamics and repeated, weak or projective measurements, give rise to new, intriguing quantum phenomena, including entanglement phase transitions and unconventional conformal invariance. Defying the complications imposed by the non-linear and stochastic nature of the measurement process, we introduce a scenario of measurement-induced many body evolution, which possesses an exact analytical solution: bosonic Gaussian measurements. The evolution features a competition between the continuous observation of linear boson operators and a free Hamiltonian, and it is characterized by a unique and exactly solvable covariance matrix. Within this framework, we then consider an elementary model for quantum criticality, the free boson conformal field theory, and investigate in which way criticality is modified under measurements. Depending on the measurement protocol, we distinguish three fundamental scenarios (a) enriched quantum criticality, characterized by a logarithmic entanglement growth with a floating prefactor, or the loss of criticality, indicated by an entanglement growth with either (b) an area-law or (c) a volume-law. For each scenario, we discuss the impact of imperfect measurements, which reduce the purity of the wavefunction and are equivalent to Markovian decoherence, and present a set of observables, e.g., real-space correlations, the relaxation time, and the entanglement structure, to classify the measurement-induced dynamics for both pure and mixed states. Finally, we present an experimental tomography scheme, which grants access to the density operator of the system by using the continuous measurement record only.

show abstract

Measurement-induced entanglement transitions in many-body localized systems

Cited by 89 publications

References 66 publications

Measurement-induced criticality and entanglement clusters: A study of one-dimensional and two-dimensional Clifford circuits

Measurement-induced criticality and entanglement clusters: A study of one-dimensional and two-dimensional Clifford circuits

Dissipative Floquet Dynamics: from Steady State to Measurement Induced Criticality in Trapped-ion Chains

Continuous gaussian measurements of the free boson CFT: A model for exactly solvable and detectable measurement-induced dynamics

Contact Info

Product

Resources

About