| Summary: | Abstract Inspired by the bottom‐up assembly in nature, an artificial self‐assembly pattern is introduced into 3D‐fused deposition modeling (FDM) printing to achieve additive manufacturing on the macroscopic scale. Thermally activated polymerization of thioctic acid (TA) enabled the bulk construction of poly(TA), and yielded unique time‐dependent self‐assembly. Freshly prepared poly(TA) can spontaneously and continuously transfer into higher‐molecular‐weight species and low‐molecular‐weight TA monomers. Poly(TA) and the newly formed TA further assembled into self‐reinforcing materials via microscopic‐phase separation. Bottom‐up self‐assembly patterns on different scales are fully realized by 3D FDM printing of poly(TA): thermally induced polymerization of TA (microscopic‐scale assembly) to poly(TA) and 3D printing (macroscopic‐scale assembly) of poly(TA) are simultaneously achieved in the 3D‐printing process; after 3D printing, the poly(TA) modes show mechanically enhanced features over time, arising from the microscopic self‐assembly of poly(TA) and TA. This study clearly demonstrates that micro‐ and macroscopic bottom‐up self‐assembly can be applied in 3D additive manufacturing.
|
|---|