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RESEARCH PRODUCT
Coherent control via weak measurements in P31 single-atom electron and nuclear spin qubits
Jeffrey C. MccallumJuha T. MuhonenJuha T. MuhonenRachpon KalraRachpon KalraArne LauchtAndrea MorelloStephanie SimmonsStephanie SimmonsAndrew S. DzurakJuan Pablo DehollainFay E. HudsonDavid N. JamiesonKohei M. Itohsubject
PhysicsPerturbation (astronomy)Spin engineering02 engineering and technologyElectron021001 nanoscience & nanotechnology01 natural sciencesCoherent controlQubitQuantum mechanics0103 physical sciencesWeak measurement010306 general physics0210 nano-technologySpin (physics)Quantum tunnellingdescription
The understanding of weak measurements and interaction-free measurements has greatly expanded the conceptual and experimental toolbox to explore the quantum world. Here we demonstrate single-shot variable-strength weak measurements of the electron and nuclear spin states of a P31 single-atom donor in silicon. We first show how the partial collapse of the nuclear spin due to measurement can be used to coherently rotate the spin to a desired pure state. We explicitly demonstrate that phase coherence is preserved with high fidelity throughout multiple sequential single-shot weak measurements and that the partial state collapse can be reversed. Second, we use the relation between measurement strength and perturbation of the nuclear state as a physical meter to extract the tunnel rates between the P31 donor and a nearby electron reservoir from data conditioned on observing no tunneling events. Our experiments open avenues to measurement-based state preparation, steering and feedback protocols for spin systems in the solid state, and highlight the fundamental connection between information gain and state modification in quantum mechanics.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2018-10-05 | Physical Review B |