Beating the Thermal Limit of Qubit Initialization with a Bayesian Maxwell’s Demon

Fault-tolerant quantum computing requires initializing the quantum register in a well-defined fiducial state. In solid-state systems, this is typically achieved through thermalization to a cold reservoir, such that the initialization fidelity is fundamentally limited by temperature. Here, we present...

Full description

Saved in:
Bibliographic Details
Published in:Physical review. X 2022-10, Vol.12 (4), p.041008, Article 041008
Main Authors: Johnson, Mark A. I., Mądzik, Mateusz T., Hudson, Fay E., Itoh, Kohei M., Jakob, Alexander M., Jamieson, David N., Dzurak, Andrew, Morello, Andrea
Format: Article
Language:English
Subjects:
Accuracy
Data analysis
Electron spin
Electron tunneling
Errors
Fault tolerance
Nuclear spin
Quantum computers
Quantum computing
Quantum nondemolition
Qubits (quantum computing)
Real time
Reduction
Reservoirs
Thermalization (energy absorption)
Thermodynamics
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Fault-tolerant quantum computing requires initializing the quantum register in a well-defined fiducial state. In solid-state systems, this is typically achieved through thermalization to a cold reservoir, such that the initialization fidelity is fundamentally limited by temperature. Here, we present a method of preparing a fiducial quantum state with a confidence beyond the thermal limit. It is based on real-time monitoring of the qubit through a negative-result measurement—the equivalent of a “Maxwell’s demon” that triggers the experiment only upon the appearance of a qubit in the lowest-energy state. We experimentally apply it to initialize an electron spin qubit in silicon, achieving a ground-state initialization fidelity of 98.9(4)%, corresponding to a20×reduction in initialization error compared to the unmonitored system. A fidelity approaching 99.9% could be achieved with realistic improvements in the bandwidth of the amplifier chain or by slowing down the rate of electron tunneling from the reservoir. We use a nuclear spin ancilla, measured in quantum nondemolition mode, to prove the value of the electron initialization fidelity far beyond the intrinsic fidelity of the electron readout. However, the method itself does not require an ancilla for its execution, saving the need for additional resources. The quantitative analysis of the initialization fidelity reveals that a simple picture of spin-dependent electron tunneling does not correctly describe the data. Our digital Maxwell’s demon can be applied to a wide range of quantum systems, with minimal demands on control and detection hardware.
ISSN:2160-3308
2160-3308
DOI:10.1103/PhysRevX.12.041008