Critical properties of the measurement-induced transition in random quantum circuits

Zabalo, Aidan; Gullans, Michael; Wilson, Justin H.; Gopalakrishnan, Sarang; Huse, David A.; Pixley, J. H.

doi:10.1103/physrevb.101.060301

Cited by 277 publications

(253 citation statements)

References 28 publications

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“…1(a). With measurements in the X basis, the transition from volume to area-law entanglement occurs at a nonzero measurement probability p X c > 0, similar to previously studied chaotic systems [9][10][11][12][13][14][15][16]18,19,[21][22][23][24][25]32,33]. On the other hand, with measurements in the Z basis, the volume law is destroyed for any nonzero p, similar to previously studied integrable systems [12,17,20].…”

Section: Systems Whose Dynamics Are Governed By An Interactingsupporting

confidence: 73%

“…As discussed in Refs. [18,33], the advantage of using the tripartite information here is that it avoids any log N divergences in the entanglement entropy at criticality, which have been observed in hybrid Haar-random circuit models [18]. Instead, I 3 is expected to scale as I 3 ∝ −N in the volume-law phase, reach an O(1) constant at criticality, and then vanish in the area-law phase.…”

Section: A Transition Diagnosticsmentioning

confidence: 99%

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Measurement-induced entanglement transitions in many-body localized systems

Lunt

Pal

2020

Phys. Rev. Research

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The resilience of quantum entanglement to a classicality-inducing environment is tied to fundamental aspects of quantum many-body systems. The dynamics of entanglement has recently been studied in the context of measurement-induced entanglement transitions, where the steady-state entanglement collapses from a volume law to an area law at a critical measurement probability p c. Interestingly, there is a distinction in the value of p c depending on how well the underlying unitary dynamics scramble quantum information. For strongly chaotic systems, p c > 0, whereas for weakly chaotic systems, such as integrable models, p c = 0. In this work, we investigate these measurement-induced entanglement transitions in a system where the underlying unitary dynamics are many-body localized (MBL). We demonstrate that the emergent integrability in an MBL system implies a qualitative difference in the nature of the measurement-induced transition depending on the measurement basis, with p c > 0 when the measurement basis is scrambled and p c = 0 when it is not. This feature is not found in Haar-random circuit models, where all local operators are scrambled in time. When the transition occurs at p c > 0, we use finite-size scaling to obtain the critical exponent ν = 1.3(2), close to the value for (2+0)-dimensional percolation. We also find a dynamical critical exponent of z = 0.98(4) and logarithmic scaling of the Rényi entropies at criticality, suggesting an underlying conformal symmetry at the critical point. This work further demonstrates how the nature of the measurement-induced entanglement transition depends on the scrambling nature of the underlying unitary dynamics. This leads to further questions on the control and simulation of entangled quantum states by measurements in open quantum systems.

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Section: Systems Whose Dynamics Are Governed By An Interactingsupporting

confidence: 73%

Section: A Transition Diagnosticsmentioning

confidence: 99%

Measurement-induced entanglement transitions in many-body localized systems

Lunt

Pal

2020

Phys. Rev. Research

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“…Recently, there have been numerous studies on 1D random quantum circuits subject to local projective (or weak) measurements [68][69][70][71][72][73][74][75][76][77][78][79][80][81]. In this model, local projective (or weak) measurements (which happens with a probability p m at each qubit site in a given time step) reduce non-trivial quantum entanglement between disjoint subsystems.…”

Section: Relation To Previous Resultsmentioning

confidence: 99%

“…Then, the remaining MPO parameters Γ α n−1 can be updated in the same way as in the bulk case, following the procedure described in Eqs. (68)- (76).…”

Section: A Canonical Update Of Mpos Under the Action Of A General Twomentioning

confidence: 99%

Efficient classical simulation of noisy random quantum circuits in one dimension

Noh

Jiang

Fefferman

2020

Quantum

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Understanding the computational power of noisy intermediate-scale quantum (NISQ) devices is of both fundamental and practical importance to quantum information science. Here, we address the question of whether error-uncorrected noisy quantum computers can provide computational advantage over classical computers. Specifically, we study noisy random circuit sampling in one dimension (or 1D noisy RCS) as a simple model for exploring the effects of noise on the computational power of a noisy quantum device. In particular, we simulate the real-time dynamics of 1D noisy random quantum circuits via matrix product operators (MPOs) and characterize the computational power of the 1D noisy quantum system by using a metric we call MPO entanglement entropy. The latter metric is chosen because it determines the cost of classical MPO simulation. We numerically demonstrate that for the two-qubit gate error rates we considered, there exists a characteristic system size above which adding more qubits does not bring about an exponential growth of the cost of classical MPO simulation of 1D noisy systems. Specifically, we show that above the characteristic system size, there is an optimal circuit depth, independent of the system size, where the MPO entanglement entropy is maximized. Most importantly, the maximum achievable MPO entanglement entropy is bounded by a constant that depends only on the gate error rate, not on the system size. We also provide a heuristic analysis to get the scaling of the maximum achievable MPO entanglement entropy as a function of the gate error rate. The obtained scaling suggests that although the cost of MPO simulation does not increase exponentially in the system size above a certain characteristic system size, it does increase exponentially as the gate error rate decreases, possibly making classical simulation practically not feasible even with state-of-the-art supercomputers.

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“…The effective spin model may also be extended to dynamics with measurement, or other types of interaction with an environment, for example, to clarify the relationship between different universality classes of measurementinduced criticality [88,89,[93][94][95][96][97][98][99][100][101][102][103].…”

Section: Discussionmentioning

confidence: 99%

Entanglement Membrane in Chaotic Many-Body Systems

2020

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In certain analytically tractable quantum chaotic systems, the calculation of out-of-time-order correlation functions, entanglement entropies after a quench, and other related dynamical observables reduces to an effective theory of an "entanglement membrane" in spacetime. These tractable systems involve an average over random local unitaries defining the dynamical evolution. We show here how to make sense of this membrane in more realistic models, which do not involve an average over random unitaries. Our approach relies on introducing effective pairing degrees of freedom in spacetime, describing a pairing of forward and backward Feynman trajectories, inspired by the structure emerging in random unitary circuits. This viewpoint provides a framework for applying ideas of coarse graining to dynamical quantities in chaotic systems. We apply the approach to some translationally invariant Floquet spin chains studied in the literature. We show that a consistent line tension may be defined for the entanglement membrane and that there are qualitative differences in this tension between generic models and "dualunitary" circuits. These results allow scaling pictures for out-of-time-order correlators and for entanglement to be taken over from random circuits to nonrandom Floquet models. We also provide an efficient numerical algorithm for determining the entanglement line tension in 1 þ 1D.

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Critical properties of the measurement-induced transition in random quantum circuits

Cited by 277 publications

References 28 publications

Measurement-induced entanglement transitions in many-body localized systems

Measurement-induced entanglement transitions in many-body localized systems

Efficient classical simulation of noisy random quantum circuits in one dimension

Entanglement Membrane in Chaotic Many-Body Systems

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