Recently, there have been various studies focusing on producing materials with different scales or developing new materials to pursue better performance of optoelectronic devices. Several optoelectronic devices like solar cells, light emitting diodes (LEDs) and photo detectors have been applied in different fields. Therefore, how to improve their efficiencies has become an essential issue. In this study, we first arranged nanoparticles (NPs) of various types and sizes to enhance the omnidirectional light harvesting of solar cells. The nanoparticles we used include titanium dioxide (TiO2), zirconium dioxide (ZrO2), aluminum oxide (Al2O3), and silicon dioxide (SiO2). In contrast to previous reports, here we focused on choosing and arranging suitable materials and varying their sizes, rather than narrowly concentrating on optimization of a single type of particle. A graded-refractive-index NP stack could minimize reflectance, not only over a broad range of wavelengths but also at different incident angles; the photocurrents of silicon-based solar cells could also be significantly improved omnidirectionally. In addition, the optical gradient of an NP stack could also enhance the light extraction efficiency of LEDs, due to both the graded refractive index and the moderate surface roughness. Large particles having sizes on the same order of the wavelength of incident light roughened the LED surfaces further and extracted light from beyond the critical angle, as supported by three-dimensional finite-difference time domain simulations. Using this approach, we could increase the photoluminescence intensity by up to six fold. Moreover, we also investigated the basic properties of gold oxide (Au2O3). Gold has been widely thought of the most inert metal. We deposited gold oxide films by sputtering process through the help of O2/Ar plasma. We discussed the optical properties and the mechanism of reduction of this special material. We conclude that gold oxide is a dielectric material with poor conductivity and high refractive index. We also discovered that when reducing, gold nanoparticles would form and can be analyzed by spectroscopy due to the LSPR (Localized surface plasmon resonance) peak around 670nm-700nm. Furthermore we also fabricated photodetectors by forming Au2O3/n-Si contact showing EQE(external quantum efficiency) near 50% in the red light and near infrared wavelength regimes with detectivity over 1012.