Tapestry of dualities in decohered quantum error correction codes
- URL: http://arxiv.org/abs/2401.17359v1
- Date: Tue, 30 Jan 2024 19:00:02 GMT
- Title: Tapestry of dualities in decohered quantum error correction codes
- Authors: Kaixiang Su, Zhou Yang, Chao-Ming Jian
- Abstract summary: Quantum error correction (QEC) codes protect quantum information from errors due to decoherence.
Many of them also serve as prototypical models for exotic topological quantum matters.
Investigating the behavior of the QEC codes under decoherence sheds light on not only the codes' robustness against errors but also new out-of-equilibrium quantum phases driven by decoherence.
- Score: 1.0301458191595498
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Quantum error correction (QEC) codes protect quantum information from errors
due to decoherence. Many of them also serve as prototypical models for exotic
topological quantum matters. Investigating the behavior of the QEC codes under
decoherence sheds light on not only the codes' robustness against errors but
also new out-of-equilibrium quantum phases driven by decoherence. The phase
transitions, including the error threshold, of the decohered QEC codes can be
probed by the systems' R\'enyi entropies $S_R$ with different R\'enyi indices
$R$. In this paper, we study the general construction of the statistical models
that characterize the R\'enyi entropies of QEC codes decohered by Pauli noise.
We show that these statistical models can be organized into a "tapestry" woven
by rich duality relations among them. For Calderbank-Shor-Steane (CSS) codes
with bit-flip and phase-flip errors, we show that each R\'enyi entropy is
captured by a pair of dual statistical models with randomness. For
$R=2,3,\infty$, there are additional dualities that map between the two error
types, relating the critical bit-flip and phase-flip error rates of the
decoherence-induced phase transitions in the CSS codes. For CSS codes with an
"$em$ symmetry" between the $X$-type and the $Z$-type stabilizers, the
dualities with $R=2,3,\infty$ become self-dualities with super-universal
self-dual error rates. These self-dualities strongly constrain the phase
transitions of the code signaled by $S_{R=2,3,\infty}$. For general stabilizer
codes decohered by generic Pauli noise, we also construct the statistical
models that characterize the systems' entropies and obtain general duality
relations between Pauli noise with different error rates.
Related papers
- Statistical mechanical mapping and maximum-likelihood thresholds for the surface code under generic single-qubit coherent errors [0.0]
We consider single-qubit coherent errors in the surface code, i.e., rotations by angle $alpha$ about an axis that can be chosen arbitrarily.
We numerically establish the existence of an error-correcting phase, which we chart in a subspace of rotation axes to estimate the corresponding maximum-likelihood thresholds.
arXiv Detail & Related papers (2024-10-29T18:23:23Z) - Hardware-efficient quantum error correction using concatenated bosonic qubits [41.6475446744259]
Quantum computers will need to incorporate quantum error correction, where a logical qubit is redundantly encoded in many noisy physical qubits.
Here, using a microfabricated superconducting quantum circuit, we realize a logical qubit memory formed from the concatenation of encoded bosonic cat qubits.
We study the performance and scaling of the logical qubit memory, finding that the phase-flip correcting repetition code operates below threshold.
arXiv Detail & Related papers (2024-09-19T18:00:53Z) - Far from Perfect: Quantum Error Correction with (Hyperinvariant) Evenbly Codes [38.729065908701585]
We introduce a new class of qubit codes that we call Evenbly codes.
Our work indicates that Evenbly codes may show promise for practical quantum computing applications.
arXiv Detail & Related papers (2024-07-16T17:18:13Z) - Perturbative stability and error correction thresholds of quantum codes [0.029541734875307393]
Topologically-ordered phases are stable to local perturbations, and topological quantum error-correcting codes enjoy thresholds to local errors.
We construct classical statistical mechanics models for decoding general CSS codes and classical linear codes.
For CSS codes satisfying the LDPC condition and with a sufficiently large code distance, we prove the existence of a low temperature ordered phase.
arXiv Detail & Related papers (2024-06-22T06:46:41Z) - Surface codes, quantum circuits, and entanglement phases [0.0]
We map 2D surface codes under a class of incoherent or coherent errors.
We find a topologically non-trivial threshold for incoherent errors and logarithmic coherent error.
Results can be generalized to other fermionic circuits and may be independent interest.
arXiv Detail & Related papers (2022-12-15T19:00:02Z) - Quantum error correction under numerically exact open-quantum-system
dynamics [0.0]
We employ numerically exact open-quantum-system dynamics to analyze the performance of a five-qubit error correction code.
Importantly, the five-qubit quantum-error correction code suppresses all single errors, including those arising from the ultrashort and short-time evolution.
Our results pave the way for applying numerically exact open-quantum-system models for the studies of QECs beyond simple error models.
arXiv Detail & Related papers (2022-12-15T10:45:44Z) - Witnessing entanglement in trapped-ion quantum error correction under
realistic noise [41.94295877935867]
Quantum Error Correction (QEC) exploits redundancy by encoding logical information into multiple physical qubits.
We present a detailed microscopic error model to estimate the average gate infidelity of two-qubit light-shift gates used in trapped-ion platforms.
We then apply this realistic error model to quantify the multipartite entanglement generated by circuits that act as QEC building blocks.
arXiv Detail & Related papers (2022-12-14T20:00:36Z) - Quantum Error Correction with Gauge Symmetries [69.02115180674885]
Quantum simulations of Lattice Gauge Theories (LGTs) are often formulated on an enlarged Hilbert space containing both physical and unphysical sectors.
We provide simple fault-tolerant procedures that exploit such redundancy by combining a phase flip error correction code with the Gauss' law constraint.
arXiv Detail & Related papers (2021-12-09T19:29:34Z) - Realizing Repeated Quantum Error Correction in a Distance-Three Surface
Code [42.394110572265376]
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.
arXiv Detail & Related papers (2021-12-07T13:58:44Z) - Exponential suppression of bit or phase flip errors with repetitive
error correction [56.362599585843085]
State-of-the-art quantum platforms typically have physical error rates near $10-3$.
Quantum error correction (QEC) promises to bridge this divide by distributing quantum logical information across many physical qubits.
We implement 1D repetition codes embedded in a 2D grid of superconducting qubits which demonstrate exponential suppression of bit or phase-flip errors.
arXiv Detail & Related papers (2021-02-11T17:11:20Z) - Avoiding coherent errors with rotated concatenated stabilizer codes [6.85316573653194]
We integrate stabilizer codes with constant-excitation codes by code concatenation.
We analyze this code's potential as a quantum memory.
arXiv Detail & Related papers (2020-10-01T16:39:21Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.