Quantum Brain
← Back to papers

A scalable helium gas cooling system for trapped-ion applications

F. R. Lebrun-Gallagher, N. Johnson, M. Akhtar, S. Weidt, D. Bretaud, Samuel J. Hile, Alexander Owens, F. Bonus, W. Hensinger·June 14, 2021·DOI: 10.1088/2058-9565/ac5d7d
Physics

AI Breakdown

Get a structured breakdown of this paper — what it's about, the core idea, and key takeaways for the field.

Abstract

Microfabricated ion-trap devices offer a promising pathway towards scalable quantum computing. Research efforts have begun to focus on the engineering challenges associated with developing large-scale ion-trap arrays and networks. However, increasing the size of the array and integrating on-chip electronics can drastically increase the power dissipation within the ion-trap chips. This leads to an increase in the operating temperature of the ion-trap and limits the device performance. Therefore, effective thermal management is an essential consideration for any large-scale architecture. Presented here is the development of a modular cooling system designed for use with multiple ion-trapping experiments simultaneously. The system includes an extensible cryostat that permits scaling of the cooling power to meet the demands of a large network. Following experimental testing on two independent ion-trap experiments, the cooling system is expected to deliver a net cooling power of 111 W at ∼70 K to up to four experiments. The cooling system is a step towards meeting the practical challenges of operating large-scale quantum computers with many qubits.

Related Research

Quantum Intelligence

Ask about quantum research, companies, or market developments.