In this work, we investigate the fabrication of a high Q-factor Si₃N₄ ring resonator by improving the propagation loss and controlling the precise control of the coupling intensity. Generally, the Si₃N₄ film was deposited on the SiO₂/Si substrate by using PECVD or LPCVD technique. However, as-deposited Si₃N₄ has dangling H and O bonds with Si and N in the films. These bonds have an intense absorption centered at 1520 nm, which overlaps with c-band and causes the excess propagation losses. In order to overcome this problem, we prepared Si₃N₄ films using the liquid source CVD (LSCVD). It turns out to be both refractive index and propagation loss can be effective optimized. In the fabrication of the Si₃N₄ ring resonator, different parameters of the ring structure are discussed in order to obtain a high- Q resonance. The measured Q factor was 70,800 and it can be further improved with increased optical confinement and film deposition optimization. When the effective refractive index assumed to change 10^-4, a resonance spectral shift of 0.093 nm can be theoretically obtained with the corresponding extinction ratio of 6 dB. Thus, a modulated depth of 3 dB within the wavelength shift of 0.046 nm is also achieved. The proposed device shows potential for high-speed, low-energy, and small-footprint optical switch and modulator application.