02540nas a2200229 4500008004100000245009600041210006900137260001300206490000700219520184300226100002102069700001802090700001402108700001502122700002802137700002302165700002302188700002402211700001802235700002002253856003702273 2022 eng d00aMany-Body Quantum Teleportation via Operator Spreading in the Traversable Wormhole Protocol0 aManyBody Quantum Teleportation via Operator Spreading in the Tra c8/5/20220 v123 a
By leveraging shared entanglement between a pair of qubits, one can teleport a quantum state from one particle to another. Recent advances have uncovered an intrinsically many-body generalization of quantum teleportation, with an elegant and surprising connection to gravity. In particular, the teleportation of quantum information relies on many-body dynamics, which originate from strongly-interacting systems that are holographically dual to gravity; from the gravitational perspective, such quantum teleportation can be understood as the transmission of information through a traversable wormhole. Here, we propose and analyze a new mechanism for many-body quantum teleportation -- dubbed peaked-size teleportation. Intriguingly, peaked-size teleportation utilizes precisely the same type of quantum circuit as traversable wormhole teleportation, yet has a completely distinct microscopic origin: it relies upon the spreading of local operators under generic thermalizing dynamics and not gravitational physics. We demonstrate the ubiquity of peaked-size teleportation, both analytically and numerically, across a diverse landscape of physical systems, including random unitary circuits, the Sachdev-Ye-Kitaev model (at high temperatures), one-dimensional spin chains and a bulk theory of gravity with stringy corrections. Our results pave the way towards using many-body quantum teleportation as a powerful experimental tool for: (i) characterizing the size distributions of operators in strongly-correlated systems and (ii) distinguishing between generic and intrinsically gravitational scrambling dynamics. To this end, we provide a detailed experimental blueprint for realizing many-body quantum teleportation in both trapped ions and Rydberg atom arrays; effects of decoherence and experimental imperfections are analyzed.
1 aSchuster, Thomas1 aKobrin, Bryce1 aGao, Ping1 aCong, Iris1 aKhabiboulline, Emil, T.1 aLinke, Norbert, M.1 aLukin, Mikhail, D.1 aMonroe, Christopher1 aYoshida, Beni1 aYao, Norman, Y. uhttps://arxiv.org/abs/2102.00010