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Quantum memory at nonzero temperature in a thermodynamically trivial system

Gorde:
Argitaratua izan da:Nature Communications vol. 16, no. 1 (2025), p. 316
Argitaratua:
Nature Publishing Group
Gaiak:
Samplers
Body temperature
Thermal stability
Error correction
Information systems
Fault tolerance
Low temperature
Topology
Phase transitions
Ising model
Codes
Sampling
Qubits (quantum computing)
Two dimensional bodies
Thermodynamics
Quantum phenomena
Error correction & detection
Parity
Temperature tolerance
Error correcting codes
Environmental
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Laburpena:Passive error correction protects logical information forever (in the thermodynamic limit) by updating the system based only on local information and few-body interactions. A paradigmatic example is the classical two-dimensional Ising model: a Metropolis-style Gibbs sampler retains the sign of the initial magnetization (a logical bit) for thermodynamically long times in the low-temperature phase. Known models of passive quantum error correction similarly exhibit thermodynamic phase transitions to a low-temperature phase wherein logical qubits are protected by thermally stable topological order. Here, in contrast, we show that certain families of constant-rate classical and quantum low-density parity check codes have no thermodynamic phase transitions at nonzero temperature, but nonetheless exhibit ergodicity-breaking dynamical transitions: below a critical nonzero temperature, the mixing time of local Gibbs sampling diverges in the thermodynamic limit. Slow Gibbs sampling of such codes enables fault-tolerant passive quantum error correction using finite-depth circuits. This strategy is well suited to measurement-free quantum error correction, and may present a desirable experimental alternative to conventional quantum error correction based on syndrome measurements and active feedback.It has been commonly assumed that self-correcting quantum memories are only possible in systems with finite-temperature phase transitions to topological order. Here the authors show a complete breakdown of this expectation in quantum low-density parity-check codes.
ISSN:2041-1723
DOI:10.1038/s41467-024-55570-7
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