AI Article Synopsis
- High-resolution surface patterning is a nonchemical technique used to create functional surfaces on 3D-printed objects, applicable in various fields like consumer products and biomedical technologies.
- A hybrid method combines 3D printing with thermal nanoimprinting, allowing for precise surface textures ranging from 2 µm to 200 nm on complex shapes like convex and concave surfaces.
- This innovative approach not only enhances the properties of 3D-printed items but also paves the way for exploring how combining microscale/nanoscale textures with larger curves impacts surface functionality.
Article Abstract
High-resolution surface patterning has garnered interests as a nonchemical-based surface engineering approach for creating functional surfaces. Applications in consumer products, parts for transportation vehicles, optics, and biomedical technologies demand topographic patterning on 3D net shape objects. Through a hybrid approach, high-resolution surface texture is incorporated onto 3D-printed polymers via direct thermal nanoimprinting process. The synergy of geometry design freedom in 3D printing and the high spatial resolution in nanoimprinting is demonstrated to be a versatile fabrication of high-fidelity surface pattern (from 2 µm to 200 nm resolution) on convex, concave semicylindrical, and hemispherical objects spanning a range of surface curvatures. The novel hybrid fabrication is further extended to achieve a high-resolution curved mold insert for rapid prototyping via injection molding. The versatility of the fabrication strategies reported here not only provides a post-3D printing process that enhances the surface properties of 3D-printed objects but also opens a new pathway to enable future study on the effects of combining microscale and nanoscale surface texture with macroscopic curvature. Both have been known, individually, as an effective approach to tune surface functionalities.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC6498116 | PMC |
| http://dx.doi.org/10.1002/gch2.201800083 | DOI Listing |
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