Repeated multi-qubit readout and feedback with a mixed-species trapped-ion register

TL;DR

This paper demonstrates repeated multi-qubit measurements and feedback in a mixed-species trapped-ion system, enabling stabilization of quantum states and advancing scalable quantum computing techniques.

Contribution

It introduces a method for high-fidelity, repeated multi-qubit readout with feedback in a mixed-species ion trap, crucial for quantum error correction.

Findings

Up to 50 sequential measurements of qubit correlations.

Successful stabilization of two-qubit subspaces and Bell states.

Implementation of feedback with negligible crosstalk and effective sympathetic recooling.

Abstract

Quantum error correction will be essential for realizing the full potential of large-scale quantum information processing devices. Fundamental to its experimental realization is the repetitive detection of errors via projective measurements of quantum correlations among qubits, and correction using conditional feedback. Performing these tasks repeatedly requires a system in which measurement and feedback decision times are short compared to qubit coherence times, where the measurement reproduces faithfully the desired projection, and for which the measurement process has no detrimental effect on the ability to perform further operations. Here we demonstrate up to 50 sequential measurements of correlations between two beryllium-ion qubits using a calcium ion ancilla, and implement feedback which allows us to stabilize two-qubit subspaces as well as Bell states. Multi-qubit mixed-species gates are used to transfer information from qubits to the ancilla, enabling quantum state detection with negligible crosstalk to the stored qubits. Heating of the ion motion during detection is mitigated using sympathetic recooling. A key element of the experimental system is a powerful classical control system, which features flexible in-sequence processing to implement feedback control. The methods employed here provide a number of essential ingredients for scaling trapped-ion quantum computing, and provide new opportunities for quantum state control and entanglement-enhanced quantum metrology.