Related papers: Deterministic remote entanglement using a chiral quantum interconnect

Deterministic remote entanglement using a chiral quantum interconnect

URL: http://arxiv.org/abs/2408.05164v1
Date: Fri, 9 Aug 2024 16:35:43 GMT
Title: Deterministic remote entanglement using a chiral quantum interconnect
Authors: Aziza Almanakly, Beatriz Yankelevich, Max Hays, Bharath Kannan, Reouven Assouly, Alex Greene, Michael Gingras, Bethany M. Niedzielski, Hannah Stickler, Mollie E. Schwartz, Kyle Serniak, Joel I-J. Wang, Terry P. Orlando, Simon Gustavsson, Jeffrey A. Grover, William D. Oliver,
Abstract summary: In this work, we construct a chiral quantum interconnect between two nominally identical modules in separate microwave packages. We leverage quantum interference to emit and absorb microwave photons on demand and in a chosen direction between these modules. We generate remote entanglement between modules in the form of a four-qubit W state with 62.4 +/- 1.6% (leftward photon propagation) and 62.1 +/- 1.2% (rightward)
Score: 0.19165511108619068
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Quantum interconnects facilitate entanglement distribution between non-local computational nodes. For superconducting processors, microwave photons are a natural means to mediate this distribution. However, many existing architectures limit node connectivity and directionality. In this work, we construct a chiral quantum interconnect between two nominally identical modules in separate microwave packages. We leverage quantum interference to emit and absorb microwave photons on demand and in a chosen direction between these modules. We optimize the protocol using model-free reinforcement learning to maximize absorption efficiency. By halting the emission process halfway through its duration, we generate remote entanglement between modules in the form of a four-qubit W state with 62.4 +/- 1.6% (leftward photon propagation) and 62.1 +/- 1.2% (rightward) fidelity, limited mainly by propagation loss. This quantum network architecture enables all-to-all connectivity between non-local processors for modular and extensible quantum computation.

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