Leveraging Secondary Storage to Simulate Deep 54-qubit Sycamore Circuits

Leveraging Secondary Storage to Simulate Deep 54-qubit Sycamore Circuits

In a recent paper, we showed that secondary storage can extend the range of quantum circuits that can be practically simulated with classical algorithms. Here we refine those techniques and apply them to the simulation of Sycamore circuits with 53 and 54 qubits, with the entanglement pattern ABCDCDA...

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Hauptverfasser: Pednault, Edwin, Gunnels, John A, Nannicini, Giacomo, Horesh, Lior, Wisnieff, Robert
Format: Artikel
Sprache:eng
Schlagworte:
Physics - Quantum Physics
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Zusammenfassung:In a recent paper, we showed that secondary storage can extend the range of quantum circuits that can be practically simulated with classical algorithms. Here we refine those techniques and apply them to the simulation of Sycamore circuits with 53 and 54 qubits, with the entanglement pattern ABCDCDAB that has proven difficult to classically simulate with other approaches. Our analysis shows that on the Summit supercomputer at Oak Ridge National Laboratories, such circuits can be simulated with high fidelity to arbitrary depth in a matter of days, outputting all the amplitudes.
DOI:10.48550/arxiv.1910.09534