Effect of spatial distribution of wax and PEG-isocyanate on the morphology and hydrophobicity of starch films

Muscat, Delina; Adhikari, Raju; Tobin, Mark; McKnight, Stafford; Wakeling, Lara; Adhikari, Benu

Title: Effect of spatial distribution of wax and PEG-isocyanate on the morphology and hydrophobicity of starch films
Creator: Muscat, Delina; Adhikari, Raju; Tobin, Mark; McKnight, Stafford; Wakeling, Lara; Adhikari, Benu
Date: 2014
Type: Text; Journal article
Identifier: http://researchonline.federation.edu.au/vital/access/HandleResolver/1959.17/167874
Identifier: vital:13742
Identifier: https://doi.org/10.1016/j.carbpol.2014.04.072
Identifier: ISBN:0144-8617
Abstract: •Synchrotron-FTIR showed the distribution of wax and PEG-isocyanate across the film.•Wax and PEG-isocyanate distributions and film surface altered the film's hydrophobicity.•High contact angle occurred when PEG-isocyanate was concentrated in the middle of the film.•Hydrophobic films possessed hierarchical wax pinnacles and textured surface.•The wax pinnacles were 10μm in diameter and distributed very closely to each other. This study proposes a novel method for improving surface hydrophobicity of glycerol plasticized high amylose (HAG) films. We used polyethylene glycol isocyanate (PEG-iso) crosslinker to link HAG and three natural waxes (beeswax, candelilla wax and carnauba wax) to produce HAG+wax+PEG-iso films. The spatial distributions of wax and PEG-iso across the thickness of these films were determined using Synchrotron-based Fourier transform infrared spectroscopy. The hydrophobicity and surface morphology of the films were determined using contact angle (CA) and scanning electron microscopic measurements, respectively. The distribution patterns of wax and the PEG-iso across the thickness of the film, and the nature of crystalline patterns formed on the surface of these films were found to be the key factors affecting surface hydrophobicity. The highest hydrophobicity (CA >90°) was created when the PEG-iso was primarily distributed in the interior of the films and a hierarchical circular pinnacle structure of solidified wax was formed on the surface.
Relation: Carbohydrate Polymers Vol. 111, no. (2014), p.
Rights: Copyright Elsevier
Rights: This metadata is freely available under a CCO license
Subject: Amylose; Natural Wax; Hydroxyl-Pegylation; Synchrotron-Based Ftir; Hydrophobicity; Surface Morphology; 0305 Organic Chemistry; 0908 Food Sciences; 0303 Macromolecular and Materials Chemistry
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