Quantum information processing in modular cavity QED architectures

TL;DR

This thesis explores quantum information processing with cavity QED, including noise spectroscopy, entanglement generation, quantum sensing, stabilizer measurements, and protocols for entangling distant qubits, advancing modular quantum computing architectures.

Contribution

It introduces novel methods for qubit noise analysis, entanglement via cavity modulation, and protocols for remote qubit entanglement, contributing to scalable quantum computing.

Findings

Quantum noise signatures can be detected via cavity output measurements.

Longitudinal coupling modulation enables qubit-path entanglement.

Photon loss during stabilizer measurements does not cause certain errors.

Abstract

This thesis contains a collection of articles exploring various aspects of quantum information processing with cavity quantum electrodynamics (QED), starting with qubit noise spectroscopy and building towards the longer-term goal of modular quantum-computing architectures equipped with protocols for controlling and correcting the states of distantly separated qubits. The first chapter presents a self-contained introduction to the field of cavity QED. Following this introductory material, we show in Chapter 2 how measurements of the field emitted by a cavity can be leveraged for in-situ qubit noise spectroscopy in the presence of significant inhomogeneous broadening. We also identify a signature of genuinely quantum noise in the cavity output field originating from the non-commutation of bath operators acting on the qubit. In Chapter 3, we present a novel quantum-optical effect whereby a suitable modulation of a longitudinal cavity-qubit coupling can be used to entangle the state of a qubit with the path taken by a multiphoton wavepacket. Entanglement between a qubit and a which-path degree-of-freedom can in turn be used to generate entanglement between distant stationary qubits. As shown in Chapter 4, qubit-which-path entanglement can also be exploited for maximally sensitive estimation of a phase in a Mach-Zehnder interferometry setup, i.e., sensing at the quantum Cram\'er-Rao bound. In Chapter 5, we discuss strategies for realizing stabilizer measurements using qubit-conditioned phase shifts applied to propagating pulses of radiation. We find that in the context of a subsystem surface code, photon loss during such stabilizer measurements would not introduce any horizontal hook errors on the code qubits. In the sixth and final chapter, we give protocols for performing entangling gates between distant stationary qubits using Fock- or time-bin encoded photons.