Generalized Zp toric codes as qudit low-density parity-check codes

Abstract

We study two-dimensional translation-invariant CSS stabilizer codes over prime-dimensional qudits on the square lattice under twisted boundary conditions, generalizing the Kitaev Zp toric code by augmenting each stabilizer with two additional qudits. Using the Laurent-polynomial formalism, we adapt the Gr\"obner basis to compute the logical dimension k efficiently, without explicitly constructing large parity-check matrices. We then perform a systematic search over various stabilizer realizations and lattice geometries for p∈\3,5,7,11\, identifying qudit low-density parity-check codes with the optimal finite-size performance. Representative examples include [[242,10,22]]3 and [[120,6,20]]11, both achieving k d2/n=20. Across the searched regime, the best observed k d2 at fixed n increases with p, with an empirical relation k d2 = 0.0541 \, n2 p + 3.84 \, n, compatible with a Bravyi--Poulin--Terhal-type tradeoff when the interaction range grows with system size.