Publication record · 18.cifr/2012.bravyi.magic-state-distillation

Magic-state distillation with low overhead

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Sergey Bravyi (IBM Watson Research Center), Jeongwan Haah (Massachusetts Institute of Technology)

RAI18.cifr/2012.bravyi.magic-state-distillation

Physical Review A· 2012· doi:10.1103/PhysRevA.86.052329

We propose a new family of protocols for distilling magic states with low overhead. The main technical tool is a new class of quantum error correcting codes that we call triorthogonal. These codes use n physical qubits to encode k logical qubits and satisfy a triorthogonality condition that enables transversal implementation of the T gate. Using triorthogonal codes, we construct magic state distillation protocols with overhead O(log^gamma(1/epsilon)) where gamma is approximately 2.46.

magic state distillationfault-tolerant quantum computationtriorthogonal codesReed-Muller codesquantum error correctionT gate

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Magic states are essential resource states for fault-tolerant universal quantum computation but cannot be prepared directly via Clifford circuits. Prior protocols required prohibitively large qubit overheads scaling poorly with target fidelity. This paper provides efficient protocols that dramatically reduce the resource cost of fault-tolerant T gates.

Novelty

Bravyi and Haah introduce triorthogonal Reed-Muller-based codes that achieve magic-state distillation with overhead scaling as O(log^gamma(1/epsilon)) with gamma near 2, surpassing the Bravyi-Kitaev gamma=3 benchmark. They construct explicit code families where multiple output magic states are produced per distillation round, improving resource efficiency.

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