Scalable, high-fidelity all-electronic control of trapped-ion qubits

TL;DR

This paper introduces a scalable, low-noise, electronically controlled trapped-ion quantum computing architecture that achieves high-fidelity single- and two-qubit gates, demonstrating its potential for large-scale quantum devices.

Contribution

The authors present a microfabricated ion trap design with shared current traces and local tuning electrodes, enabling scalable, high-fidelity quantum gate operations with low crosstalk.

Findings

Achieved 99.99916% fidelity for single-qubit gates.

Generated 99.97% fidelity two-qubit entangled states.

Demonstrated stable performance over continuous operation.

Abstract

The central challenge of quantum computing is implementing high-fidelity quantum gates at scale. However, many existing approaches to qubit control suffer from a scale-performance trade-off, impeding progress towards the creation of useful devices. Here, we present a vision for an electronically controlled trapped-ion quantum computer that alleviates this bottleneck. Our architecture utilizes shared current-carrying traces and local tuning electrodes in a microfabricated chip to perform quantum gates with low noise and crosstalk regardless of device size. To verify our approach, we experimentally demonstrate low-noise site-selective single- and two-qubit gates in a seven-zone ion trap that can control up to 10 qubits. We implement electronic single-qubit gates with 99.99916(7)% fidelity, and demonstrate consistent performance with low crosstalk across the device. We also electronically generate two-qubit maximally entangled states with 99.97(1)% fidelity and long-term stable performance over continuous system operation. These state-of-the-art results validate the path to directly scaling these techniques to large-scale quantum computers based on electronically controlled trapped-ion qubits.