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Coherent control via weak measurements in ³¹P single-atom electron and nuclear spin qubits

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arxiv 1702.07991 v1 pith:IBRFUUEF submitted 2017-02-26 quant-ph cond-mat.mes-hall

Coherent control via weak measurements in ³¹P single-atom electron and nuclear spin qubits

classification quant-ph cond-mat.mes-hall
keywords statemeasurementsspinnuclearweakelectroncollapsedemonstrate
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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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 the nuclear spin states of a single $^{31}$P 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 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 tunneling rates between the $^{31}$P 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.

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