Quantum error correction via multi-particle discrete-time quantum walk

Abstract

We propose a scheme of quantum error correction that employs a multi-particle quantum walk defined on nested squares, each hosting a single particle. In this model, each particle moves within its own distinct square through iterations of three discrete-time steps. First, a particle updates its two-level internal coin state. Next, it either moves to an adjacent vertex or stays put, depending on the outcome. Finally, it interacts with another particle if these particles arrive at the nearest-neighbor vertices of the two adjacent squares, acquiring a phase factor of $-1$. Because a single particle represents a three-qubit state through its position and coin state, Shor's nine-qubit code is implemented using only three particles, with two additional particles for syndrome measurement. Furthermore, by exploiting gauge symmetry, our scheme achieves redundant encoding, error correction, and arbitrary operations on the encoded information using only nearest-neighbor interactions.