Electronically-controlled one- and two-qubit gates for transmon quasicharge qubits (2510.20127v1)

Abstract: Superconducting protected qubits aim to achieve sufficiently low error rates so as to allow realization of error-corrected, utility-scale quantum computers. A recent proposal encodes a protected qubit in the quasicharge degree of freedom of the conventional transmon device, here referred to as the `quasicharge qubit'. Operating such a protected qubit requires implementing new strategies. Here we show that an electronically-controllable tunnel junction formed by two topological superconductors can be used to implement single- and two-qubit gates on quasicharge qubits. Schemes for both these gates are based on dynamical $4\pi$-periodic Josephson effect and therefore have gate speeds of the same order. The simulation of the dynamics of a topological Josephson junction in a parameter regime with non-negligible charging energy is the key novelty of this work. We also characterize the robustness of such gate operations against charge noise using Fermi's golden rule. Our results point to a compelling strategy for implementation of quasicharge qubit gates based on junctions of minimal Kitaev chains of quantum dots.