Radial Fast Entangling Gates Under Micromotion in Trapped-Ion Quantum Computers

TL;DR

This paper shows that micromotion in trapped-ion quantum computers, usually seen as harmful, can actually be exploited to design fast, high-fidelity entangling gates within hundreds of nanoseconds.

Contribution

It introduces a novel approach to utilize micromotion in radial modes for fast quantum gates, challenging the conventional view of micromotion as purely detrimental.

Findings

High-fidelity entangling gates achieved in hundreds of nanoseconds.

Micromotion enhances gate speed and fidelity in radial modes.

Feasibility demonstrated under realistic experimental noise conditions.

Abstract

Micromotion in radio-frequency ion traps is generally considered detrimental for quantum logic gates, and is typically minimized in state-of-the-art experiments. However, as a deterministic effect, it can be incorporated into quantum control frameworks aimed at designing high-fidelity quantum logic controls. In this work, we demonstrate that micromotion can be beneficial to the design of fast gates utilizing the radial modes of a two-ion crystal, particularly in the sub-trap-period regime where high-fidelity control sequences are identified with operation times ranging from hundreds of nanoseconds to microseconds. Through analysis of select fast gate solutions, we uncover the physical origin of micromotion enhancement and further study the induced gate error under experimental noises and control imperfections. This analysis establishes the feasibility of realising high-fidelity entangling gates in hundreds of nanoseconds using the micromotion-sensitive radial modes of trapped-ion crystals.