The first part of this thesis covers the design and implementation of a spectral ellipsometer at near-infrared wavelength (700-1000nm) for samples placed in high magnetic fields (up to 14 Tesla) at low temperatures (~4.2 K). It details both the optical and mechanical aspects of the system in the low temperature environment. The main optical components are integrated in a probe, which can be inserted into a conventional long-neck He dewar and has a very long free-space optical path (~1.8 m x 2). A polarizer-sample-(quarter-wave plate)-rotating analyzer configuration was employed. Two dielectric mirrors, one before and one after the sample in the optical path, helped to reflect the light back to the analyzer and a two-axis piezo-driven goniometer under the sample holder was used to control the direction of the reflected light. Functional test results and analysis on the random error of the system are shown. The properties of GaAs polariton propagating in magnetic field have been explored using this self-designed ellipsometry system. We obtained both the amplitude and phase ellipsometric spectra simultaneously and observed helicity transformation at energies near the GaAs exciton transitions in the phase spectra. Interesting fine structures, which have not been reported before, have been observed and their magneto-optical behavior cannot be accounted by the known properties of excitonic states. Treating the surface and the growth interface as boundaries, we attribute the fine structures to the interference among various polariton modes. A model considering both the polariton spatial dispersion and the exciton effective mass enhancement induced by the coupling of the exciton center of mass and relative motions is proposed to explain the magnetic response of the interference ellipsometry spectra. In the second part of this thesis, we propose an ideal to design a special kind of semiconductor quantum wells, which, in contrary to conventional quantum wells, are able to provide smaller electron transport effective mass and higher mobility when the quantum well thickness is decreased. The theory used accounts for both the nonparabolicity effect and the influence of the barrier. Major scattering mechanisms at low temperatures, including the scatterings by the interface roughness, the alloy disorder, and impurities have been considered in mobility calculations. The results of four different combinations of quantum wells are shown and compared. By properly choosing the well/barrier materials with proper band lineups, the novel transport property is achievable.