High-fidelity single-shot readout for a spin qubit via an enhanced latching mechanism.

In this work, we study the mechanisms and benefits of an enhanced latching readout for semiconductor spin qubits that generates a signal of larger amplitude, that persists for longer than the conventional spin blockade. The readout of spin states relies on a spin-to-charge conversion mechanism that maps spin states to a transient charge state detected by a charge sensor. We use a silicon quantum dot coupled to a single donor atom to form a singlet-triplet qubit. The asymmetric coupling to charge reservoirs produces latching in the charge transitions. We show that this can be used to extend the lifetime of the charge readout signal by several orders of magnitude. The latched state also produces an enhanced charge signal of one additional electron that improves the signal-to-noise ratio by factors of two, four or even thousands depending on the system's geometry. Using single shot readout, we demonstrate average readout fidelities > 99.3% and > 99.86% for the conventional and enhanced readout respectively, the latter being the highest to date for spin blockade. We furthermore highlight that the results apply generally to singlet-triplet and all-exchange qubit systems. This readout relaxes layout constraints because the charge sensor signal is no longer dependent on being aligned with the conventional (2,0)-(1,1) charge dipole.