Fast quantum logic gates with trapped-ion qubits

TL;DR

This paper demonstrates a method for implementing fast, high-fidelity two-qubit quantum gates with trapped-ion qubits using tailored laser pulses, significantly surpassing previous speed limits and reducing errors.

Contribution

It introduces a laser pulse shaping technique that enables MHz-rate quantum gates in trapped ions, achieving sub-microsecond operation times with high fidelity and robustness.

Findings

Achieved entanglement with gate times as short as 480 ns.

Demonstrated a 1.6 μs gate with 99.8% fidelity.

Gate error reduced by over ten times compared to conventional methods.

Abstract

Quantum bits based on individual trapped atomic ions constitute a promising technology for building a quantum computer, with all the elementary operations having been achieved with the necessary precision for some error-correction schemes. However, the essential two-qubit logic gate used for generating quantum entanglement has hitherto always been performed in an adiabatic regime, where the gate is slow compared with the characteristic motional frequencies of ions in the trap, giving logic speeds of order 10kHz. There have been numerous proposals for performing gates faster than this natural "speed limit" of the trap. We implement the method of Steane et al., which uses tailored laser pulses: these are shaped on 10 ns timescales to drive the ions' motion along trajectories designed such that the gate operation is insensitive to optical phase fluctuations. This permits fast (MHz-rate) quantum logic which is robust to this important source of experimental error. We demonstrate entanglement generation for gate times as short as 480ns; this is less than a single oscillation period of an ion in the trap, and 8 orders of magnitude shorter than the memory coherence time measured in similar calcium-43 hyperfine qubits. The method's power is most evident at intermediate timescales, where it yields a gate error more than ten times lower than conventional techniques; for example, we achieve a 1.6 us gate with fidelity 99.8%. Still faster gates are possible at the price of higher laser intensity. The method requires only a single amplitude-shaped pulse and one pair of beams derived from a continuous-wave laser, and offers the prospect of combining the unrivalled coherence properties, operation fidelities and optical connectivity of trapped-ion qubits with the sub-microsecond logic speeds usually associated with solid state devices.