Realizing Repeated Quantum Error Correction in a Distance-Three Surface
Code
- URL: http://arxiv.org/abs/2112.03708v1
- Date: Tue, 7 Dec 2021 13:58:44 GMT
- Title: Realizing Repeated Quantum Error Correction in a Distance-Three Surface
Code
- Authors: Sebastian Krinner, Nathan Lacroix, Ants Remm, Agustin Di Paolo, Elie
Genois, Catherine Leroux, Christoph Hellings, Stefania Lazar, Francois
Swiadek, Johannes Herrmann, Graham J. Norris, Christian Kraglund Andersen,
Markus M\"uller, Alexandre Blais, Christopher Eichler, and Andreas Wallraff
- Abstract summary: We demonstrate quantum error correction using the surface code, which is known for its exceptionally high tolerance to errors.
In an error correction cycle taking only $1.1,mu$s, we demonstrate the preservation of four cardinal states of the logical qubit.
- Score: 42.394110572265376
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Quantum computers hold the promise of solving computational problems which
are intractable using conventional methods. For fault-tolerant operation
quantum computers must correct errors occurring due to unavoidable decoherence
and limited control accuracy. Here, we demonstrate quantum error correction
using the surface code, which is known for its exceptionally high tolerance to
errors. Using 17 physical qubits in a superconducting circuit we encode quantum
information in a distance-three logical qubit building up on recent
distance-two error detection experiments. In an error correction cycle taking
only $1.1\,\mu$s, we demonstrate the preservation of four cardinal states of
the logical qubit. Repeatedly executing the cycle, we measure and decode both
bit- and phase-flip error syndromes using a minimum-weight perfect-matching
algorithm in an error-model-free approach and apply corrections in
postprocessing. We find a low error probability of $3\,\%$ per cycle when
rejecting experimental runs in which leakage is detected. The measured
characteristics of our device agree well with a numerical model. Our
demonstration of repeated, fast and high-performance quantum error correction
cycles, together with recent advances in ion traps, support our understanding
that fault-tolerant quantum computation will be practically realizable.
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