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    Spatiotemporal Nonlinear Optical Effects in Multimode Fibers
    (2022) Dacha, Sai Kanth; Murphy, Thomas E; Physics; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    The advent of the optical fiber in the second half of the 20th century has had numerous consequences not only for the advancement of telecommunication and information transfer technologies, but also for humanity as a whole. At the time of writing of this thesis, we live in a world that is defined by unprecedented and unparalleled access to information made possible by fiber optic cables that line the ocean beds. As the world becomes increasingly reliant upon the internet, the demand for access is outgrowing the pace at which the capacity of our fiber optic networks can be scaled up. In the past decade, a consensus has emerged among researchers in academia and the industry that we are now approaching the fundamental classical capacity limit of a conventional single mode fiber, namely the Shannon limit. This has spurred interest in multimode fibers that allow for hundreds of spatial modes to co-propagate, potentially allowing for at least an order of magnitude increase in capacity per fiber. While multiplexing in the spatial domain has the potential to offer significantly higher capacities, linear and nonlinear mixing between the spatial modes of a fiber are expected to play an important role in determining the capacity and performance of spatially multiplexed telecommunication systems. So far, multimode fibers have mostly been relegated to low-power short- distance links, as a result of which nonlinear propagation effects in the presence of multiple spatial modes has received relatively little attention. This thesis adds to a growing body of literature that is increasingly interested in uncovering the physics of multimodal propagation in the nonlinear regime. Although the need for spatial multiplexing is important factor driving research interest in this topic, experiments in recent years have revealed a plethora of complex spatiotemporal non- linear phenomena occurring in multimode fibers, including Kerr-induced beam self-cleaning, parametric instability processes and the existence of multimode solitons. This has sparked great interest in understanding multimodal nonlinearity from a fundamental and applied physics per- spective. Nonlinear multimode fiber optics is also of central importance for the development of high power fiber-coupled lasers as the larger core size of multimode fibers allow for far higher power throughput than current state-of-the-art lasers based on single mode fibers. Most literature reported thus far in multimodal nonlinear optics focuses on complex phe- nomena occurring when hundreds of spatial modes co-propagate in the nonlinear regime. While that has proven to be a fascinating field of study, there have not been many studies on experimental investigation of intermodal nonlinear effects in the presence of a small number of spatial modes. Furthermore, nonlinear phenomena in multimode fibers are ‘spatiotemporal’ in nature, meaning that the spatial and time-domain waveforms are intertwined, and the two degrees of freedom cannot be separated. Conventional measurement techniques are not capable of resolving such a multimodal beam in space and time simultaneously. Finally, most research involving nonlinear optical effects has thus far focused on linearly polarized modes in conventional fibers, and nonlinear effects involving vector orbital angular momentum modes remains relatively understudied. In this thesis, we seek to study nonlinear optical effects involving a small number of selectively excited scalar as well as vector spatial modes, and to develop experimental techniques capable of resolving the output in both space, frequency and time. To this end, we design, prototype and fabricate devices and methods aimed at exciting a small number of spatial modes of a fiber. In particular, we adopt methods from integrated photonics such as focused ion beam milling and metasurface devices to selectively excite modes of a fiber in an efficient manner. Spatial and temporal resolution of the output beam is achieved by the development of a new technique that involves raster-scanning of a near-field scanning optical microscopy probe, coupled with a high speed detector, along the output end-face of the fiber. Using these methods, we uncover and report our observations of spatiotemporal nonlinear phenomena that are unique to multimodal systems. We first demonstrate nonlinear intermodal interference of radially symmetric modes in step-index and parabolic index fibers. We then apply the same spatiotemporal measurement technique to observe the Kerr-induced beam self-cleaning phenomenon in a parabolic index fiber. And finally, we discuss our discovery of a spin-orbit coupled generalization of the well-known nonlinear polarization rotation phenomenon.
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    New Technologies for Broadband Quantum Key Distribution: Sources, Detectors, and Systems
    (2008-11-12) Rogers, Daniel; Goldhar, Julius; Chemical Physics; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    In this thesis I describe three independent projects that advance the development of broadband quantum cryptography. While each project pertains to a different part of the QKD chain, together they provide key developments in implementing QKD at bit rates that are practical for use in the modern telecommunications infrastructure. The first project comprises the bulk of the thesis and involves developing a novel source of correlated photon pairs for use in free-space QKD. This source is based on a birefringent semiconductor optical waveguide as a Kerr medium. We demonstrate the feasibility of using birefringent phase-matched four-wave mixing to generate correlated photon pairs. We further propose that, by reversing the process and pumping with conjugate wavelengths, one can use the same effect to produce entangled photon pairs with the same device. These pairs can then be used for QKD to realize the most secure and efficient quantum cryptographic data links. The second project examines the implications of operating a BB84 QKD protocol at clock rates that are faster than the recovery time of the constituent detectors. We show that operating such systems under conventional protocols results in a security violation that allows an eavesdropper to learn significant information about the key and present a modification to the BB84 protocol that maintains key security at fast transmission rates. This modification to the protocol will become vital to QKD viability as links become faster and clock rates go into the tens of gigahertz. We also demonstrate, rather counterintuitively, that there exists an optimal transmission rate for a QKD system that exceeds the inverse of an individual detector's dead time. The final project describes a new design for a free-space QKD link that centers around faster silicon detectors. These detectors have a peak quantum efficiency in the visible range, requiring that the system operate at a wavelength that is more susceptible to solar interference. To mitigate this effect, the link is designed around a Fraunhofer line in the solar spectrum where the background solar light levels are reduced by up to 90%. By implementing this system, we expect at least a two-fold increase in the secret key rate, coming ever closer to the goal of a 10 Mb/s QKD system compatible with first-generation ethernet technology.