Quantum information technologies demand highly accurate control over quantum systems.
Achieving this requires control techniques that perform well despite the presence of …

Coherent control of individual molecular spins in nanodevices is a pivotal prerequisite for
fulfilling the potential promised by molecular spintronics. By applying electric field pulses …

The electronic and nuclear spin degrees of freedom of donor impurities in silicon form ultra-
coherent two-level systems, that are potentially useful for applications in quantum …

Single‐crystal EPR experiments show that the highly symmetric antiferromagnetic half‐
integer spin triangle [Fe3O (O2CPh) 6 (py) 3] ClO4⋅ py (1, py= pyridine) possesses a ST …

Phosphorus donor impurities in silicon are a promising candidate for solid-state quantum
computing due to their exceptionally long coherence times and high fidelities. However …

Donor electron spins in semiconductors make exceptional qubits because of their long
coherence times and compatibility with industrial fabrication techniques. Despite many …

Recent work has shown that electron spins in germanium (Ge) nanoscale transistors can be
electrically tuned and have encouraging coherence times. Based on a complete and …

Over the past decade, donor spin qubits in isotopically enriched Si 28 have been intensely
studied due to their exceptionally long coherence times. More recently, bismuth donor …

This work reports the measurement of electron g-factor anisotropy (| Δ g|=| g 001− g 1 1¯ 0|)
for phosphorous donor qubits in strained silicon (sSi= Si/Si 1− x Ge x) environments …

Effective Hamiltonian engineering is a powerful technique that utilises time-dependent
perturbation theory to suppress or enhance certain effects that arise from otherwise weak …