Low Overhead Qutrit Magic State Distillation

Abstract

We show that using qutrits rather than qubits leads to a substantial reduction in the overhead cost associated with an approach to fault-tolerant quantum computing known as magic state distillation. We construct a family of [[9m-k, k, 2]]3 triorthogonal qutrit error-correcting codes for any positive integers m and k with k ≤ 3m-2 that are suitable for magic state distillation. In magic state distillation, the number of ancillae required to produce a magic state with target error rate ε is O(γ ε-1), where the yield parameter γ characterizes the overhead cost. For k=3m-2, our codes have γ = 2 (2+63 m-2), which tends to 1 as m ∞. Moreover, the [[20,7,2]]3 qutrit code that arises from our construction when m=3 already has a yield parameter of 1.51 which outperforms all known qubit triorthogonal codes of size less than a few hundred qubits.