Related papers: A compact ion-trap quantum computing demonstrator

A compact ion-trap quantum computing demonstrator

URL: http://arxiv.org/abs/2101.11390v3
Date: Mon, 7 Jun 2021 10:59:04 GMT
Title: A compact ion-trap quantum computing demonstrator
Authors: Ivan Pogorelov, Thomas Feldker, Christian D. Marciniak, Lukas Postler, Georg Jacob, Oliver Krieglsteiner, Verena Podlesnic, Michael Meth, Vlad Negnevitsky, Martin Stadler, Bernd H\"ofer, Christoph W\"achter, Kirill Lakhmanskiy, Rainer Blatt, Philipp Schindler, Thomas Monz
Abstract summary: We present a 19-inch rack quantum computing demonstrator based on $40textrmCa+$ optical qubits in a linear Paul trap. We describe the automation and remote access components of the quantum computing stack. We produce maximally-entangled Greenberger-Horne-Zeilinger states with up to 24 ions without the use of post-selection or error mitigation techniques.
Score: 1.1054689759565857
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Quantum information processing is steadily progressing from a purely academic discipline towards applications throughout science and industry. Transitioning from lab-based, proof-of-concept experiments to robust, integrated realizations of quantum information processing hardware is an important step in this process. However, the nature of traditional laboratory setups does not offer itself readily to scaling up system sizes or allow for applications outside of laboratory-grade environments. This transition requires overcoming challenges in engineering and integration without sacrificing the state-of-the-art performance of laboratory implementations. Here, we present a 19-inch rack quantum computing demonstrator based on $^{40}\textrm{Ca}^+$ optical qubits in a linear Paul trap to address many of these challenges. We outline the mechanical, optical, and electrical subsystems. Further, we describe the automation and remote access components of the quantum computing stack. We conclude by describing characterization measurements relevant to digital quantum computing including entangling operations mediated by the Molmer-Sorenson interaction. Using this setup we produce maximally-entangled Greenberger-Horne-Zeilinger states with up to 24 ions without the use of post-selection or error mitigation techniques; on par with well-established conventional laboratory setups.

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