High-fidelity all-electronic control of trapped-ion qubits

Clemens Loschnauer; Amy C Hughes; Raghavendra Srinivas; Jacopo Mosca Toba; Marius Weber; Maciej Malinowski; Roland Matt; Steven A King; Clemens Matthiesen; Thomas Harty; Chris Ballance

High-fidelity all-electronic control of trapped-ion qubits

POSTER

Abstract

Electronic control of trapped-ion qubits offers a promising route towards a large-scale quantum computing processor. It has delivered some of the highest-fidelity quantum gates ever reported [1, 2] and is highly scalable as it allows integrating control signals directly into the trap chip. We present progress towards all-electronic control of trapped-ion qubits at Oxford Ionics, including a demonstration of high-fidelity two-qubit entangling gates with a duration of approximately 100 µs using an integrated microwave antenna. We thus reach the typical speed of laser-based gates in a highly scalable architecture.

[1] T. P. Harty et al., Phys. Rev. Lett. 117, 140501 (2016)

[2] R. Srinivas et al., Nature 597, pp 209-213 (2021)

Presenters

Clemens Loschnauer
- Oxford Ionics

Authors

Clemens Loschnauer
- Oxford Ionics
Amy C Hughes
- Oxford Ionics
Raghavendra Srinivas
- Oxford Ionics
Jacopo Mosca Toba
- Oxford Ionics
Marius Weber
- Oxford Ionics
Maciej Malinowski
- Oxford Ionics
Roland Matt
- Oxford Ionics
Steven A King
- Oxford Ionics
Clemens Matthiesen
- Oxford Ionics
- Institute of Physics
Thomas Harty
- Oxford Ionics
Chris Ballance
- Oxford Ionics