Epoxy Networks with Physical Crosslinks Produced by Tail-to-Tail Associations of Alkyl Chains

J. PUIG; I. A. ZUCCHI; C. E. HOPPE; C. J. PÉREZ; M. J. GALANTE; R. J. J. WILLIAMS; C. RODRÍGUEZ-ABREU

MACROMOLECULES

AMER CHEMICAL SOC

Lugar: Washington, USA; Año: 2009 vol. 42 p. 9344 - 9350

0024-9297

In a recent paper (I. A. Zucchi et al. Macromolecules 2008, 41, 4895) we showed that linear amphiphilic epoxy polymers synthesized by the polyaddition of diglycidyl ether of bisphenol A (DGEBA) with dodecylamine (DA) could undergo a physical gelation process through tail-to-tail association of dodecyl chains. The aim of the present study was to analyze in more detail conditions leading to the formation of epoxy networks with physical crosslinks by the reaction of DGEBA with alkylamines of different chain lengths: octylamine (OA), dodecylamine (DA) and hexadecylamine (HA). SAXS spectra showed that tail-to-tail associations of alkyl chains were present since the beginning of polymerization and remained in the final materials. Initially, these associations correspond to micelles of the alkylamines dispersed in the solvent (DGEBA). In the course of polymerization micelles are disaggregated as the individual alkylamine chains become part of the linear amphiphilic polymer. However, tail-to-tail associations among alkyl chains attached to the polymer backbone persisted in the final materials. Reactions were followed by rheometry at 100 ºC. For every system, a significant discontinuity in the increase in the storage modulus observed at advanced conversions was assigned to a phase inversion process produced by solvent depletion. By annealing prolonged times at the reaction temperature a cross-over of storage and loss modulus was observed due to the increase in the extent of associations among alkyl chains leading to a physical gel. Times for physical gelation varied in the order OA < DA < HA. Both DGEBA-DA and DGEBA-HA polymers could be reversibly transformed from gel to liquid states by appropriate heating-cooling cycles; however, the DGEBA-OA polymer showed no thermoreversibility. Physical gels exhibited a high swelling capacity in THF (HA > DA > OA). These amphiphilic gels could be used as dispersion media for a variety of nanoparticles stabilized with alkyl chains. They can also be the basis of single-component thermally remendable epoxy networks.