Effects of leakage on the realization of a discrete time crystal in a chain of singlet-triplet qubits

TL;DR

This paper investigates how leakage affects the realization of a discrete time crystal in a chain of singlet-triplet qubits, showing that alternating magnetic fields can suppress leakage and restore the DTC phase.

Contribution

It demonstrates that leakage can destroy the DTC phase in singlet-triplet qubit chains but can be mitigated with specific magnetic field configurations, guiding experimental implementations.

Findings

DTC phase exists without leakage in ideal models.

Uniform magnetic fields do not suppress leakage, destroying DTC.

Alternating magnetic fields can restore DTC by suppressing leakage.

Abstract

We consider the effects of leakage on the ability to realize a discrete time crystal (DTC) in a semiconductor quantum dot linear array being operated as a chain of singlet-triplet (ST) qubits. This system realizes an Ising model with an effective applied magnetic field, plus additional terms that can cause leakage out of the computational subspace. We demonstrate that, in the absence of these leakage terms, this model theoretically realizes a DTC phase over a broad parameter regime for six and eight qubits, with a broader parameter range for the eight-qubit case. We then reintroduce the leakage terms and find that the DTC phase disappears entirely over the same parameter range if the system is only subject to a uniform magnetic field, which does not suppress leakage. However, we find that the DTC phase can be restored if the system is instead subject to a magnetic field that alternates from qubit to qubit, which suppresses leakage. We thus show that leakage is a serious problem for the realization of a DTC phase in a chain of ST qubits, but is by no means insurmountable. Our work suggests that experiments manifesting small-system stable DTC should be feasible with currently existing quantum dot spin qubits.