Strong coupling between light and matter has been demonstrated both in classical
cavity quantum electrodynamics (QED) systems and in more recent circuit-QED
experiments. This enables the generation of strong nonlinear photon-photon interactions
at the single-photon level, which is of great interest for the observation
of quantum nonlinear optical phenomena, the control of light quanta in quantum
information protocols such as quantum networking, as well as the study of
strongly correlated quantum many-body systems using light. Recently, strong
coupling has also been realized in a variety of one-dimensional (1D) waveguide-
QED experimental systems, which in turn makes them promising candidates for
quantum information processing. Compared to cavity-QED systems, there are
two new features in waveguide-QED: the existence of a continuum of states and
the restricted 1D phase space, which together bring in new physical effects, such
as the bound-state effects. This thesis consists of two parts: 1) understanding the
fundamental interaction between local quantum objects, such as two-level systems
and four-level systems, and photons confined in the waveguide; 2) exploring
its implications in quantum information processing, in particular photonic
quantum computation and quantum key distribution.
First, we demonstrate that by coupling a two-level system (TLS) or three/fourlevel
system to a 1D continuum, strongly-correlated photons can be generated
inside the waveguide. Photon-photon bound states, which decay exponentially as a function of the relative coordinates of photons, appear in multiphoton scattering
processes. As a result, photon bunching and antibunching can be observed
in the photon-photon correlation function, and nonclassical light source can be
generated on demand. In the case of an N-type four-level system, we show
that the effective photon-photon interaction mediated by the four-level system,
gives rise to a variety of nonlinear optical phenomena, including photon blockade,
photon-induced tunneling, and creation of single-photon states and photon
pairs with a high degree of spectral entanglement, all in the absence of a cavity.
However, to enable greater quantum networking potential using waveguide-
QED, it is important to study systems having more than just one TLS/qubit.
We develop a numerical Green function method to study cooperative effects in
a system of two qubits coupled to a 1D waveguide. Quantum beats emerge in
photon-photon correlations, and persist to much longer time scales because of
non-Markovian processes. In addition, this system can be used to generate a
high-degree of long-distance entanglement when one of the two qubits is driven
by an on-resonance laser, further paving the way toward waveguide-QED-based
quantum networks.
Furthermore, based on our study of light-matter interactions in waveguide-
QED, we investigate its implications in quantum information processing. First,
we study quantum key distribution using the sub-Possonian single photon source
obtained by scattering a coherent state off a two-level system. The rate for key
generation is found to be twice as large as for other sources. Second, we propose
a new scheme for scalable quantum computation using flying qubits--propagating
photons in a one-dimensional waveguide--interacting with matter qubits. Photonphoton
interactions are mediated by the coupling to a three- or four-level system,
based on which photon-photon -phase gates (Controlled-NOT) can be implemented for universal quantum computation. We show that high gate fidelity is
possible given recent dramatic experimental progress in superconducting circuits
and photonic-crystal waveguides. The proposed system can be an important
building block for future on-chip quantum networks.