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Asymmetric Blockade and Multiqubit Gates via Dipole-Dipole Interactions

Jeremy T. Young, Przemysław Bienias, Ron Belyansky, Adam M. Kaufman, Alexey V. Gorshkov

2021Physical Review Letters56 citationsDOIOpen Access PDF

Abstract

Because of their strong and tunable interactions, Rydberg atoms can be used to realize fast two-qubit entangling gates. We propose a generalization of a generic two-qubit Rydberg-blockade gate to multiqubit Rydberg-blockade gates that involve both many control qubits and many target qubits simultaneously. This is achieved by using strong microwave fields to dress nearby Rydberg states, leading to asymmetric blockade in which control-target interactions are much stronger than control-control and target-target interactions. The implementation of these multiqubit gates can drastically simplify both quantum algorithms and state preparation. To illustrate this, we show that a 25-atom Greenberger-Horne-Zeilinger state can be created using only three gates with an error of 5.8%.

Topics & Concepts

QubitRydberg formulaQuantum gatePhysicsRydberg atomToffoli gateQuantum computerQuantum mechanicsTopology (electrical circuits)QuantumComputer scienceMathematicsCombinatoricsIonIonizationQuantum Information and CryptographyCold Atom Physics and Bose-Einstein CondensatesQuantum Computing Algorithms and Architecture
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