Direct glass-to-glass bonding obtained via simplified ammonia-based low-temperature procedure resists high shear stress and powerful CW fiber laser irradiation

Direct glass-to-glass bonding is important for high-technology components in optics, microfluidics, and micro-electromechanical systems applications. We studied direct bonding of 1 mm thick soda-lime float glass substrates. The process is based on the classic RCA-1 cleaning procedure from the semiconductor industry modified with an ammonium hydroxide rinse, followed by a thermal treatment under unidirectional pressure without the need for a dedicated drying step. RCA-1 uses a solution of ammonium hydroxide and hydrogen peroxide to clean contaminants off the surface of silicon and enable subsequent bonding. Bond quality was evaluated using destructive shear testing. Strong bonds (approximate to 7.81 MPa on average) were achieved using unidirectional pressure of approximately 0.88 MPa and bonding temperatures between 160 degrees C and 300 degrees C applied for 30 min. Surface roughness and chemistry was characterized before and after cleaning. The optical robustness of the bonds was tested and shown to be capable of surviving high powered continuous wave (CW) fiber laser irradiation of at least 375 W focused for 2 s without delamination. Melting of the substrate was observed at higher powers and longer exposure times.

Automated summary

Direct glass-to-glass bonding is crucial for high-technology applications in optics, microfluidics, and micro-electromechanical systems. In this study, we investigated the bonding process of 1 mm thick soda-lime float glass substrates. By modifying the classic RCA-1 cleaning procedure and applying unidirectional pressure along with thermal treatment, we achieved strong bonds with an average shear strength of approximately 7.81 MPa. The bonded glass substrates exhibited robustness against high powered continuous wave fiber laser irradiation without delamination.