Hybrid bonding is a promising technology for 3D packaging, enabling the simultaneous formation of fine interconnects and dielectric layers. To address the limitations of conventional SiO2, such as its vulnerability to Cu diffusion, silicon carbonitride (SiCN) has emerged as a superior alternative due to its low-k properties and effectiveness as a diffusion barrier. This study investigates the SiCN-SiCN bonding characteristics under various process parameters, including bonding pressure, annealing pressure, and annealing temperature, following an O2 plasma surface activation. The plasma treatment was found to be effective, reducing the surface roughness from 0.23 nm to 0.16 nm and drastically lowering the water contact angle from 70.5° to 4.36°. Transmission electron microscopy (TEM) analysis of the bonded interface revealed the formation of an intermediate oxide layer. A systematic comparison showed that the application of pressure during either the initial room-temperature bonding or the subsequent annealing step was essential for a successful bond. Furthermore, the bonded area and overall bonding strength exhibited a clear positive correlation with increases in bonding pressure, annealing pressure, and temperature.