Stronger aramids through molecular design and nanoprocessing
文献信息
Amalia Rapakousiou, Alejandro López-Moreno, Belén Nieto-Ortega, M. Mar Bernal, Miguel A. Monclús, Santiago Casado, Cristina Navío, Luisa R. González, Juan P. Fernández-Blázquez, Juan J. Vilatela, Emilio M. Pérez
We introduce oligo-(1,6-pyrene terephthalamide, oPyrTA) as an oligoamide model for Kevlar®. Through comparison with an oligo-(p-phenylene terephthalamide, oPTA) of similar molecular weight, this work shows that the incorporation of polycyclic aromatic pyrene moieties improves drastically the mechanical properties of the structure, increasing elastic nanoindentation-determined modulus and hardness by factors of 1.9 and 4.3, respectively. Liquid deprotonated dispersions of oPyrTA nanofibers were used as nanoscale building blocks for producing large-surface, free-standing oligomer macroscopic nanofilms. This 2D assembly leads to further significant improvements in reduced modulus and hardness (more than twice) compared to the starting oligomer macroscale fibres, due to a better re-organizational arrangement of the oPyrTA nanofibers in the nanofilms, formed under 2D spatial confinement.
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Polymer Chemistry

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