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arxiv 1210.6644 v2 pith:O6YYLN2G submitted 2012-10-24 quant-ph hep-th

Scrambling speed of random quantum circuits

classification quant-ph hep-th
keywords scramblingdepthquantumcircuitsrandomcircuitinformationalpha
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Random transformations are typically good at "scrambling" information. Specifically, in the quantum setting, scrambling usually refers to the process of mapping most initial pure product states under a unitary transformation to states which are macroscopically entangled, in the sense of being close to completely mixed on most subsystems containing a fraction fn of all n particles for some constant f. While the term scrambling is used in the context of the black hole information paradox, scrambling is related to problems involving decoupling in general, and to the question of how large isolated many-body systems reach local thermal equilibrium under their own unitary dynamics. Here, we study the speed at which various notions of scrambling/decoupling occur in a simplified but natural model of random two-particle interactions: random quantum circuits. For a circuit representing the dynamics generated by a local Hamiltonian, the depth of the circuit corresponds to time. Thus, we consider the depth of these circuits and we are typically interested in what can be done in a depth that is sublinear or even logarithmic in the size of the system. We resolve an outstanding conjecture raised in the context of the black hole information paradox with respect to the depth at which a typical quantum circuit generates an entanglement assisted encoding against the erasure channel. In addition, we prove that typical quantum circuits of poly(log n) depth satisfy a stronger notion of scrambling and can be used to encode alpha n qubits into n qubits so that up to beta n errors can be corrected, for some constants alpha, beta > 0.

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  1. Operator spreading in random circuits with orthogonal or symplectic symmetry

    quant-ph 2026-06 unverdicted novelty 7.0

    Random circuits with orthogonal or symplectic symmetry exhibit ternary Pauli weights, finite-width domain walls, and component-dependent butterfly velocities that can exceed the Haar value for q=2.