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Geometric Pathway to Scalable Quantum Sensing

Mattias Johnsson, Nabomita Roy Mukty, Daniel Burgarth, Thomas Volz, Gavin K. Brennen

2020Physical Review Letters26 citationsDOIOpen Access PDF

Abstract

Entangled resources enable quantum sensing that achieves Heisenberg scaling, a quadratic improvement on the standard quantum limit, but preparing large N spin entangled states is challenging in the presence of decoherence. We present a quantum control strategy using highly nonlinear geometric phase gates which can be used for generic state or unitary synthesis on the Dicke subspace with O(N) or O(N^{2}) gates, respectively. The method uses a dispersive coupling of the spins to a common bosonic mode and does not require addressability, special detunings, or interactions between the spins. By using amplitude amplification our control sequence for preparing states ideal for metrology can be significantly simplified to O(N^{5/4}) geometric phase gates with action angles O(1/N) that are more robust to mode decay. The geometrically closed path of the control operations ensures the gates are insensitive to the initial state of the mode and the sequence has built-in dynamical decoupling providing resilience to dephasing errors.

Topics & Concepts

PhysicsQuantum gateQuantum decoherenceGeometric phaseDynamical decouplingQuantum mechanicsSpinsQuantumTopology (electrical circuits)Quantum computerMathematicsCondensed matter physicsCombinatoricsQuantum Information and CryptographyAtomic and Subatomic Physics ResearchQuantum and electron transport phenomena
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