Regulating cell morphology of poly (lactic acid) foams from microcellular to nanocellular by crystal nucleating agent

The inherent shortcomings of poor melt strength and crystallization behavior constrain the foamability and mechanical properties of poly (lactic acid) (PLA). In this work, a crystal nucleating agent was introduced into PLA system to solve the aforementioned issues by manipulating crystallization process. Isothermal crystallization results implied that the crystal nucleating agent promoted PLA crystallization greatly, where the adjusted ranges of crystallization rate and crystallinity were expanded obviously. Results indicated that the modified PLA foams displayed a mixed distribution of nanoscale and microscale cells at low temperatures, while the uniform pentagonal shape cells emerged in the foams prepared at 112 degrees C. Accordingly, the cell size decreased from 44.62 mu m to 360 nm, and the cell density increased from 9.06x10(8) cells/cm(3) to 7.48x10(13) cells/cm(3). Moreover, the compressive strength of the modified foams was enhanced notably than that of pure PLA foams. Overall, the crystallization and foaming properties of PLA were analyzed systematically, the foaming properties were improved significantly by controlling proper crystallization, and this work would provide a prospective strategy to fabricate high performance PLA foams with controllable cell structures and high compression properties.

Automated summary

In this study, a crystal nucleating agent was introduced into poly (lactic acid) (PLA) system to improve its foamability and mechanical properties. The results showed that the crystal nucleating agent greatly promoted PLA crystallization, and by controlling the crystallization process, PLA foams with controllable cell structures and high compression properties were obtained.