The high throughput investigation of polyphenolic couplers in biodegradable packaging materials

Our goal is to select and develop stimuli–responsive interfacial coupling materials for nanocomposites that will enhance substrate mechanical properties during use but cause triggered disintegration when exposed to the appropriate aqueous environment. The study could potentially provide the scientif...

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Bibliographic Details
Published in:Applied surface science 2006-01, Vol.252 (7), p.2535-2548
Main Authors: Lochhead, Robert Y., Haynes, Camille T., Jones, Stephen R., Smith, Virginia
Format: Article
Language:English
Subjects:
Biodegradable packing material
Cross-disciplinary physics: materials science
rheology
Exact sciences and technology
FT-IR
Materials science
Other materials
Physics
Polymers and plastics
rubber
synthetic and natural fibers
organometallic and organic materials
Polyphenolic coupler
Specific materials
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Summary:Our goal is to select and develop stimuli–responsive interfacial coupling materials for nanocomposites that will enhance substrate mechanical properties during use but cause triggered disintegration when exposed to the appropriate aqueous environment. The study could potentially provide the scientific underpinning for the development of an interfacially interacting nanocomposite alloy capable of enhanced biodegradation in the aqueous environment. In the first stage of this study it was shown that quaternary ammonium polymers adsorbed on the faces of the montmorillonite platelets, non-ionic polyacrylamides adsorbed on the faces and edges by hydrogen bonding, and anionic polyelectrolytes, carboxylates and sulfonates, did not adsorb at all on the montmorillonite [R.Y. Lochhead, C.L. McConnell-Boykin, An investigative study of polymer adsorption to smectite clay: polyelectrolytes and sodium montmorillonite, in: R. Krishnamoorti, R. Vaia (Eds.), Polymer Nanocomposites, American Chemical Society, 2002; R.Y. Lochhead, C.L. McConnell-Boykin, C. Haynes, Interaction of hydrophilic polymers with smectite clays, Polymer Materials Science and Engineering, vol. 85, American Chemical Society, 2001, p. 419]. The objective of the second part of the study was to examine model polymers in order to guide research aimed at designing coupling polymers that would cause exfoliation of the clay. Based upon the earlier study, polyvinylamine was chosen as the model on the basis that it is a simple polymer with primary amine groups and the polymer charge density could be modified by simply changing the system pH. The aim of this research was to determine the conditions under which polyvinylamine, and selected derivatives of this polymer, would penetrate the galleries of the stacked montmorillonite platelets. The knowledge gained could be applied to predict systems that would facilitate intercalation or exfoliation of sodium montmorillonite. The investigative approach of the third stage was to create a coupler from the hydrogen-bonded coacervate formed between a polyphenolic compound and polyvinylpyrrolidone, and to use this to exfoliate and couple montmorillonite nanoparticles to polycaprolactone. To achieve this, solubility parameter mapping of candidate polymeric couplers, polycaprolactone and target polyphenolic compounds was undertaken. This was used as a screening process in predicting incompatibilities and eliminating unpromising materials that were soluble in the same material
ISSN:0169-4332
1873-5584
DOI:10.1016/j.apsusc.2005.08.113