This study presents the development and successful 3D printing of siloxane composite. Complex structures are 3D printed using vector‐scanning stereolithography apparatus. Siloxane oligomer and a commercial resin in the presence of an appropriate photoinitiator combine to form a hybrid material that photopolymerizes when exposed to UV laser at 405 nm wavelength. Measurements with differential scanning calorimetry, thermogravimetric analysis, dynamic mechanical analysis, universal testing machine (UTM), and material testing system (MTS) reveal various properties of methacrylate resin filled with different concentrations of siloxane. Fourier transform infrared and Raman spectroscopy results reveal molecular structural change due to chemical reaction with the siloxane introduction. Atomic force microscopy imaging displays the surface morphology characteristics of the hybrid polymer while the contact angle confirms the surface energy existing on the samples. The 3D‐printed structures show unique physicochemical and thermomechanical properties that can lead to great potential for new applications in the field. This work is the first comprehensive study on 3D printing using siloxane through stereolithography.
This study deals with the investigation of photocurable thiol‐yne resins covering several important aspects for the production of medical devices by UV‐based manufacturing processes. In this context, the performance of different low‐toxic photoinitiators (PIs) and stabilizers are evaluated in thiol‐yne formulations based on di(but‐1‐yn‐4‐yl) carbonate and various multifunctional thiol monomers. Photodifferential scanning calorimetry measurements reveal that the conversion of all resin formulations is mostly independent on the type and concentration of the applied photoinitiator; however, significant differences in their curing speed are observed. It turns out that the migration of an alkyne derivatized photoinitiator is significantly reduced while providing almost similar photoactivity as its nonfunctionalized reference. Moreover, it is found that lauryl gallate and butylated hydroxytoluene lead to significant stabilization without affecting the overall photoreactivity. Notably, the thermomechanical properties of the investigated photopolymers are only slightly affected by water absorption. Using ester free thiols, water absorption can be reduced and hydrolytically stable polymers are realized. These results highlight the versatility of the present thiol‐yne system for the production of medical materials by photopolymerization.
Synthesis, properties, and patterning of new acrylic/silsesquioxane hybrid materials are reported. PMA‐functionalized PHSSQ was synthesized by hydrosilylation and then formulated with acrylate monomer mixtures to yield the photocurable materials. Experiments suggest that the thermal/mechanical properties of the parent acrylic polymers could be significantly enhanced by incorporating nano‐sized silsesquioxane moieties. The refractive index and optical loss were reduced by increasing the silsesquioxane content. The hybrid materials could be photocured and developed a Y‐shape channel pattern; potential applications include uses in patterned electronic and optoelectronic devices.
