Nature Communications (Feb 2024)

Rapid exchange cooling with trapped ions

  • Spencer D. Fallek,
  • Vikram S. Sandhu,
  • Ryan A. McGill,
  • John M. Gray,
  • Holly N. Tinkey,
  • Craig R. Clark,
  • Kenton R. Brown

DOI
https://doi.org/10.1038/s41467-024-45232-z
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 9

Abstract

Read online

Abstract The trapped-ion quantum charge-coupled device (QCCD) architecture is a leading candidate for advanced quantum information processing. In current QCCD implementations, imperfect ion transport and anomalous heating can excite ion motion during a calculation. To counteract this, intermediate cooling is necessary to maintain high-fidelity gate performance. Cooling the computational ions sympathetically with ions of another species, a commonly employed strategy, creates a significant runtime bottleneck. Here, we demonstrate a different approach we call exchange cooling. Unlike sympathetic cooling, exchange cooling does not require trapping two different atomic species. The protocol introduces a bank of “coolant" ions which are repeatedly laser cooled. A computational ion can then be cooled by transporting a coolant ion into its proximity. We test this concept experimentally with two 40Ca+ ions, executing the necessary transport in 107 μs, an order of magnitude faster than typical sympathetic cooling durations. We remove over 96%, and as many as 102(5) quanta, of axial motional energy from the computational ion. We verify that re-cooling the coolant ion does not decohere the computational ion. This approach validates the feasibility of a single-species QCCD processor, capable of fast quantum simulation and computation.