A lower bound on the space overhead of fault-tolerant quantum computation

TL;DR

This paper establishes a fundamental lower bound on the number of physical qubits needed for fault-tolerant quantum computation, relating it to the quantum channel capacity and circuit parameters, thus advancing understanding of quantum resource requirements.

Contribution

It provides a general lower bound on space overhead in fault-tolerant quantum schemes considering realistic noise models, improving previous bounds by allowing qubit replacement and perfect classical computation.

Findings

Lower bound of max{Q(N)^{-1} n, α_N log T} on physical qubits

Exponential upper bound on fault-tolerant circuit length with amplitude damping noise

Improved bounds by allowing qubit replacement and perfect classical computation

Abstract

The threshold theorem is a fundamental result in the theory of fault-tolerant quantum computation stating that arbitrarily long quantum computations can be performed with a polylogarithmic overhead provided the noise level is below a constant level. A recent work by Fawzi, Grospellier and Leverrier (FOCS 2018) building on a result by Gottesman (QIC 2013) has shown that the space overhead can be asymptotically reduced to a constant independent of the circuit provided we only consider circuits with a length bounded by a polynomial in the width. In this work, using a minimal model for quantum fault tolerance, we establish a general lower bound on the space overhead required to achieve fault tolerance. For any non-unitary qubit channel $\mathcal{N}$ and any quantum fault tolerance schemes against $\mathrm{i.i.d.}$ noise modeled by $\mathcal{N}$, we prove a lower bound of $\max\left\{\mathrm{Q}(\mathcal{N})^{-1}n,\alpha_\mathcal{N} \log T\right\}$ on the number of physical qubits, for circuits of length $T$ and width $n$. Here, $\mathrm{Q}(\mathcal{N})$ denotes the quantum capacity of $\mathcal{N}$ and $\alpha_\mathcal{N}>0$ is a constant only depending on the channel $\mathcal{N}$. In our model, we allow for qubits to be replaced by fresh ones during the execution of the circuit and we allow classical computation to be free and perfect. This improves upon results that assumed classical computations to be also affected by noise, and that sometimes did not allow for fresh qubits to be added. Along the way, we prove an exponential upper bound on the maximal length of fault-tolerant quantum computation with amplitude damping noise resolving a conjecture by Ben-Or, Gottesman, and Hassidim (2013).