In this thesis, we introduce two device applications of Guide-mode resonance (GMR). First one is broad-band reflector for far infrared on GaAs substrate, we deposit low refractive index material SiOx, and then fabricate a two-dimensional triangular lattice grating made by high refractive index Ge. With this structure, we have obtained a reflector with 95% high reflectivity at 8μm. The reflector can be integrated with far infrared photonic device such as quantum dot infrared photodetector (QDIP). Second device is wavelength sensitive PIN photodetector using guided-mode resonance for 0.95 μm. The cavity is formed by bottom distributed Bragg reflector (DBR) and top GMR grating to enhance detection efficiency. By changing the filling factor of the grating, effective cavity length can be tuned. Therefore, we can fabricate an array of resonant cavity enhanced (RCE) photodiodes on a single chip, on which every photodiode aims for a specific wavelength by means of GMR grating design. In this thesis, we discuss the design principle based on grating diffraction theory, wave guide theory and equivalent medium theory. We aim at the analysis of the design, fabrication and experimental results of the two device applications to verify that GMR is feasible to be integrated into photonic devices.