Distillation with sublogarithmic overhead

Abstract

It has been conjectured [1] that for any distillation protocol for magic states for the T gate, the number of noisy input magic states required per output magic state at output error rate ε is ((1/ε)). We show that this conjecture is false. We find a family of quantum error correcting codes of parameters [[Σi=w+1m mi, Σi=0w mi, Σi=w+1r+1 r+1i]] for any integers m > 2r, r > w 0, by puncturing quantum Reed-Muller codes. When m > r, our code admits a transversal logical gate at the -th level of Clifford hierarchy. In a distillation protocol for magic states at the level = 3 (T-gate), the ratio of input to output magic states is O(γ (1/ε)) where γ = (n/k)/(d)< 0.678 for some m,r,w. The smallest code in our family for which γ < 1 is on ≈ 258 qubits.