This thesis is divided into two parts; the first part reports results from studies on perovskite (MAPbI3) by using temperature dependent photoluminescence spectroscopy and x-ray diffraction techniques. The photoexcited emission peak positions, intensity, and full width at half maximum (FWHM) were recorded when the temperature was scanned from 300 K to 10 K. The second part demonstrates the fabrication of perovskite solar cells and the enhancement of cell performance by the combination of improving the perovskite filling in TiO2 layer and surface passivation. From the XRD spectra, a phase transition from the tetragonal phase (at room temperature) to the orthorhombic phase begin to take place when the temperature of perovskite was cooled down to ~ 150 K. Clear PL signals originated from the orthorhombic phase were observed around 110 K ~ 120 K. With increased temperature, the luminescence peak of the tetragonal phase first showed slightly blue-shifted from 1.596 eV to 1.598 eV at 40 K and then was red-shifted to 1.57 eV at 130 K. Above 130 K, the energy peak was again blue-shifted to 1.61 eV with temperature increased toward 300K. The luminescence peak of the orthorhombic phase showed only slightly blue-shifted from 1.66 eV to 1.67 eV with temperature increased from 10 K to 120 K. Narrowing of the FWHM of the luminescence peak of the tetragonal phase from 105 meV to 49 meV was observed with increased temperature from 10 K to 120 K. Above 120 K, the FWHM began to broaden and reached 94 meV at 300 K. The FWHM of the luminescence peak of the orthorhombic phase decreased from 43 meV to 38 meV with decreased temperature from 100 K to 10 K. In the scanning electron microscope images, nano scale grains with an average size of ~ 10 nm were observed in the MAPbI3 thin film. We speculate that, due to the presence of the nano grains, localized states were induced within the energy gap of MAPbI3 due to the quantum confinement effect. The observed temperature dependent behavior in photoluminescence spectra, which is similar to those observed in the self-assembly semiconductor quantum dots, was attributed to the presence of localized states induced by the MAPbI3 nano scale grains. The mesoporous perovskite solar cells were demonstrated with an initial efficiency of 6.5% by using a two-step deposition method. By spinning PbI2 for two times to provide a better perovskite loading, the efficiency was improve to 8%. The efficiency was further improved to 9.7% by using the silanol to passivate the uncoordinated halide on the interface, which led to reduced surface recombination and enhanced carrier transport.