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Ion trap with in-vacuum high numerical aperture imaging for a dual-species modular quantum computer

Allison L. Carter, Jameson O’Reilly, George Toh, Sagnik Saha, Mikhail I. Shalaev, Isabella Goetting, C. Monroe

2024Review of Scientific Instruments11 citationsDOIOpen Access PDF

Abstract

Photonic interconnects between quantum systems will play a central role in both scalable quantum computing and quantum networking. Entanglement of remote qubits via photons has been demonstrated in many platforms; however, improving the rate of entanglement generation will be instrumental for integrating photonic links into modular quantum computers. We present an ion trap system that has the highest reported free-space photon collection efficiency for quantum networking. We use a pair of in-vacuum aspheric lenses, each with a numerical aperture of 0.8, to couple 10(1)% of the 493 nm photons emitted from a 138Ba+ ion into single-mode fibers. We also demonstrate that proximal effects of the lenses on the ion position and motion can be mitigated.

Topics & Concepts

Trapped ion quantum computerQuantum entanglementQubitPhysicsPhotonQuantum computerQuantum sensorQuantum networkQuantum imagingQuantum technologyPhotonicsIon trapQuantumQuantum simulatorQuantum informationAperture (computer memory)Cavity quantum electrodynamicsModular designIonTrap (plumbing)OpticsQuantum mechanicsComputer scienceOpen quantum systemAcousticsOperating systemMeteorologyQuantum Information and CryptographyQuantum optics and atomic interactionsNeural Networks and Reservoir Computing
Ion trap with in-vacuum high numerical aperture imaging for a dual-species modular quantum computer | Litcius