Next-Generation Rydberg Atom Array Quantum Platform
POSTER
Abstract
Rydberg atom arrays have emerged as one of the leading platforms for quantum computation and simulation, with systems already consisting of hundreds of physical qubits and gate fidelities surpassing quantum error correction thresholds. Further scaling of this system requires maintaining this exquisite level of control over orders of magnitude more physical qubits and pushing two-qubit gate errors significantly farther below threshold, all while continuously reloading the small fraction of atomic qubits lost during gate operations. A next-generation Rydberg atom array experiment is becoming operational at Harvard, and aims to be a testbed for the technical advancements required for this scaling. In this poster, we will describe these efforts to scale up the number of physical qubits, continuously reload lost atoms without decoherence of remaining data qubits, and further suppress two-qubit gate errors from current values.
*We acknowledge financial support from the U.S. Department of Energy (DOE Quantum Systems Accelerator Center), the DARPA ONISQ program, the Center for Ultracold Atoms (an NSF Physics Frontier Center), the National Science Foundation, the Army Research Office MURI, IARPA and the Army Research Office, under the Entangled Logical Qubits program and QuEra Computing. M.A. acknowledges support by a Rubicon Grant from the Netherlands Organization for Scientific Research (NWO).
Presenters
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Jinen Guo
- Harvard University