Composing p-adic qubits: from representations of SO(3)p to entanglement and universal quantum logic gates

Abstract

In the context of p-adic quantum mechanics, we investigate composite systems of p-adic qubits and p-adically controlled quantum logic gates. We build on the notion of a single p-adic qubit as a two-dimensional irreducible representation of the compact p-adic special orthogonal group SO(3)p. We show that the classification of these representations reduces to the finite case, as they all factorise through some finite quotient SO(3)p mod pk. Then, we tackle the problem of p-adic qubit composition and entanglement, fundamental for a p-adic formulation of quantum information processing. We classify the representations of SO(3)p mod p, and analyse tensor products of two p-adic qubit representations lifted from SO(3)p mod p. We solve the Clebsch-Gordan problem for such systems, revealing that the coupled bases decompose into singlet and doublet states. We further study entanglement arising from those stable subsystems. For p=3, we construct a set of gates from 4-dimensional irreducible representations of SO(3)p mod p that we prove to be universal for quantum computation.