Polydimethylsiloxane (PDMS) is extensively employed in applications ranging from flexible electronics to microfluidics due to its elasticity, transparency, and biocompatibility. However, enhancing interfacial adhesion and tensile properties remains a challenge for applications demanding high mechanical stability. To this end, this study introduced a novel bonding technique using crosslinkers as adhesive layers to improve the mechanical performance of PDMS. By adjusting the crosslink density at the PDMS-PDMS interfaces, we achieved substantial improvements in tensile properties and interfacial adhesion. Our findings revealed that, under specific conditions, a particular mixing ratio significantly enhances the elastic modulus and interfacial stability. Notably, the elastic modulus of PDMS with a tailored crosslink density increased by approximately 760% compared to that achieved with a simple bonding method. This study demonstrated an effective strategy for tailoring the interfacial properties of PDMS by adjusting the crosslink density, offering a pathway to enhance material design for applications requiring advanced mechanical performance and stability.
Keywords: PDMS-PDMS bonding technique; crosslink density; mechanical testing; polydimethylsiloxane (PDMS); tunable tensile properties.