Abstract

In this paper, AlxGa1−xN films on Si substrates were synthesized with adjusting process parameters by magnetron sputtering and high ammoniated two-step method innovatively, while gallium oxide was used as gallium target, and aluminum was used as aluminum target, ammonia gas and nitrogen were used as nitrogen source. The influence of process parameters on the quality of AlxGa1−xN films was researched with X-ray diffraction (XRD), scanning electron microscope (SEM), and Energy Diffraction Spectrum (EDS) for the prepared samples. The results showed that AlxGa1−xN film can be grown on the Si substrate by magnetron sputtering and high ammoniated two-step method, and substrate temperature, sputtering power, nitrogen concentration also have a great impact on the quality of AlxGa1−xN film. The sample was developed along (002) peak preferred with high orientation at 200 °C. High-quality film could be grown when the x is 0.32 in AlxGa1−xN films grown in 300 °C substrate temperature, 150 W sputtering power and 50% nitrogen concentration conditions, which is used for gas sensitive sensor. And compared stress by the measurement of Raman with an excitation wavelength λ = 532 nm. The samples were tested by photoluminescence (PL), which indicated two light-emitting peaks at 405 nm and 645 nm when the excitation wavelength is 325 nm. The measure in Hall Effect Measurement System showed that the carrier concentration and mobility were changed with different Al components.

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