Fast, robust and laser-free universal entangling gates for trapped-ion quantum computing

TL;DR

This paper introduces a fast, robust, laser-free two-qubit entangling gate for trapped-ion quantum computing that surpasses previous methods in speed and coherence, with high fidelity and scalability potential.

Contribution

The paper presents a novel, experimentally demonstrated entangling gate using phase-modulated continuous driving fields, significantly improving speed and noise resilience over prior rf-controlled gates.

Findings

Gate speed is an order of magnitude higher than previous rf gates.

Qubit coherence time is increased by three orders of magnitude.

Bell states are generated with up to 98% fidelity in under 313 microseconds.

Abstract

A novel two-qubit entangling gate for trapped-ion quantum processors is proposed theoretically and demonstrated experimentally. During the gate, double-dressed quantum states are created by applying a phase-modulated continuous driving field. The speed of this quantum gate is an order of magnitude higher than that of previously demonstrated rf controlled two-qubit entangling gates in static magnetic field gradients. At the same time, the field driving the gate dynamically decouples the qubits from amplitude and frequency noise, increasing the qubits' coherence time by $3$ orders of magnitude. The gate requires only a single continuous rf field per qubit, making it well suited for scaling a quantum processor to large numbers of qubits. Implementing this entangling gate, we generate the Bell states $|\Phi^+\rangle$ and $|\Psi^+\rangle$ in less than or equal to $313$ $\mathrm{\mu}$s with fidelities up to $98^{+2}_{-3}$% in a static magnetic gradient of only $19.09$ T/m. At higher magnetic field gradients, the entangling gate speed can be further improved to match that of laser-based counterparts.