Gunther, Aimee Kirsten2018-08-032018-08-032018-08-032018-07-20http://hdl.handle.net/10012/13537While quantum properties of light promise much-needed enhancements to metrology, further development of quantum light sources and associated tools are needed to readily harness two-photon interactions via energy-time correlations. This thesis will discuss the experimental development of energy-time correlated photon pairs generated within the nonlinear material of bulk periodically-poled lithium niobate toward photon pair up-conversion. Joint spatial-spectral characterizations of this spontaneous parametric down-conversion source are modelled and measured using a unique single-shot spatial-spectral method. In addition, another telecommunication-wavelength entangled photon pair source is simulated and experimentally characterized through dispersive time-of-flight measurements. As required by the goal of biphoton frequency conversion, a prism compressor for enacting biphoton dispersion cancellation was built and later characterized using wavelength-scanning interferometry. With the amalgamation of these components and techniques, an experimental study of biphoton frequency conversion is constructed and characterized to elucidate this femtosecond-timescale quantum frequency conversion process.enquantum opticsquantum frequency conversionspontaneous parametric down-conversionultrafast opticsenergy-time correlationsnonlinear opticsquantum physicsDoctoral Thesis