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Finite speed of quantum scrambling with long range interactions

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arxiv 1907.07637 v3 pith:CRMH56IL submitted 2019-07-17 quant-ph cond-mat.str-elmath-phmath.MP

Finite speed of quantum scrambling with long range interactions

classification quant-ph cond-mat.str-elmath-phmath.MP
keywords quantuminteractionsalphafiniteinformationlongrangescrambling
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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In a locally interacting many-body system, two isolated qubits, separated by a large distance $r$, become correlated and entangled with each other at a time $t \ge r/v$. This finite speed $v$ of quantum information scrambling limits quantum information processing, thermalization and even equilibrium correlations. Yet most experimental systems contain long range power law interactions -- qubits separated by $r$ have potential energy $V(r)\propto r^{-\alpha}$. Examples include the long range Coulomb interactions in plasma ($\alpha=1$) and dipolar interactions between spins ($\alpha=3$). In one spatial dimension, we prove that the speed of quantum scrambling remains finite for sufficiently large $\alpha$. This result parametrically improves previous bounds, compares favorably with recent numerical simulations, and can be realized in quantum simulators with dipolar interactions. Our new mathematical methods lead to improved algorithms for classically simulating quantum systems, and improve bounds on environmental decoherence in experimental quantum information processors.

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