Abstract
Quantum data are susceptible to decoherence induced by the environment and to errors in the hardware processing it. A future fault-tolerant quantum computer will use quantum error correction to actively protect against both. In the smallest error correction codes, the information in one logical qubit is encoded in a two-dimensional subspace of a larger Hilbert space of multiple physical qubits. For each code, a set of non-demolition multi-qubit measurements, termed stabilizers, can discretize and signal physical qubit errors without collapsing the encoded information. Here using a five-qubit superconducting processor, we realize the two parity measurements comprising the stabilizers of the three-qubit repetition code protecting one logical qubit from physical bit-flip errors. While increased physical qubit coherence times and shorter quantum error correction blocks are required to actively safeguard the quantum information, this demonstration is a critical step towards larger codes based on multiple parity measurements.
Highlights
Quantum data are susceptible to decoherence induced by the environment and to errors in the hardware processing it
The true merit of quantum error correction (QEC) hinges on the ability to suppress the accumulation of errors
We believe that a better comparison is the logical state fidelity FL following two rounds of errors with QEC or idling in between
Summary
Quantum data are susceptible to decoherence induced by the environment and to errors in the hardware processing it. Measuring stabilizers can discretize and signal single bit-flip errors without affecting the encoded information (that is, the probability amplitudes a and b). We demonstrate stabilizer-based QEC on the minimal unit of encoded quantum information, a logical qubit, restricting to bit-flip errors.
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