Percolation thresholds for photonic quantum computing

Abstract

Any quantum algorithm can be implemented by an adaptive sequence of single node measurements on an entangled cluster of qubits in a square lattice topology. Photons are a promising candidate for encoding qubits but assembling a photonic entangled cluster with linear optical elements relies on probabilistic operations. Given a supply of n-photon-entangled microclusters, using a linear optical circuit and photon detectors, one can assemble a random entangled state of photons that can be subsequently "renormalized" into a logical cluster for universal quantum computing. In this paper, we prove that there is a fundamental tradeoff between n and the minimum success probability λc(n) that each two-photon linear-optical fusion operation must have, in order to guarantee that the resulting state can be renormalized: λc(n) 1/(n-1). We present a new way of formulating this problem where λc(n) is the bond percolation threshold of a logical graph and provide explicit constructions to produce a percolated cluster using n=3 photon microclusters (GHZ states) as the initial resource. We settle a heretofore open question by showing that a renormalizable cluster can be created with 3-photon microclusters over a 2D graph without feedforward, which makes the scheme extremely attractive for an integrated-photonic realization. We also provide lattice constructions, which show that 0.5 λc(3) 0.5898, improving on a recent result of λc(3) 0.625. Finally, we discuss how losses affect the bounds on the threshold, using loss models inspired by a recently-proposed method to produce photonic microclusters using quantum dot emitters.