Abstract
There is a considerable demand for the development and application of polymer materials in the flexible electronic- and polymer-based electrolyte technologies. Chitosan (CS) and poly(2-ethyl-2-oxazoline) (POZ) materials were blended with different ratios to obtain CS:POZ blend films using a straightforward solution cast technique. The work was involved a range of characteristic techniques, such as impedance spectroscopy, X-ray diffraction (XRD), and optical microscopy. From the XRD spectra, an enhancement in the amorphous nature in CS:POZ blend films was revealed when compared to the pure state of CS. The enhancement was verified from the peak broadening in CS:POZ blend films in relative to the one in crystalline peaks of the CS polymer. The optical micrograph study was used to designate the amorphous and crystalline regions by assigning dark and brilliant phases, respectively. Upon increasing POZ concentration, the dielectric constant was found to increase up toɛ′ = 6.48 (at 1 MHz) at 15 wt.% of POZ, and then a drop was observed beyond this amount. The relatively high dielectric constant and dielectric loss were found at elevated temperatures. The increase of POZ concentration up to 45 wt.% made the loss tangent to shift to the lower frequency side, which is related to increasing resistivity. The increases of dielectric constant and dielectric loss with temperature were attributed to the increase of polarisation. The loss tangent peaks were found to shift to the higher frequency side as temperature elevated. Obvious relaxation peaks were observed in the imaginary part of electric modulus, and no peaks were found in the dielectric loss spectra. The concentration dependent ofM″ peaks was found to follow the same trend of loss tangent peaks versus POZ content. The relaxation process was studied in terms of electric modulus parameters.
Highlights
Chitosan (CS) is a linear polysaccharide, bioderivative of the second most abundant natural chitin polymer after cellulose [1], which is obtained mainly from shells of crustaceans, jelly sh, or corals. e advantage of CS over the other polysaccharides is based on its biocompatibility and a variety of interesting properties, such as anti-in ammatory, antimicrobial, antitumor, and immunity-enhancement properties
It is clearly observed that the dark and brilliant region may appear in optical microscope (OM) images as a result of the structural behaviour of the blend films. e dark regions are attributed to amorphous phases, whereas the radiant phases or spherulites relate to crystalline areas [13]. e present work revealed that the OM technique has shown a powerful ability to observe the structural change which occurs in polymer composites and polymer blend systems [3, 13, 29]
It revealed that the OM technique is capable of detecting the neutral silver particles in chitosan-based polymer electrolytes via the appearance of brilliant white spots or white chains on the polymer surface [3, 13]. e close inspection at adjusted magnification (274.3) indicates that the spherulites due to amorphous phase cover the surface and small brilliant regions ascribed to the crystalline area appeared
Summary
Chitosan (CS) is a linear polysaccharide, bioderivative of the second most abundant natural chitin polymer after cellulose [1], which is obtained mainly from shells of crustaceans, jelly sh, or corals. e advantage of CS over the other polysaccharides is based on its biocompatibility and a variety of interesting properties, such as anti-in ammatory, antimicrobial, antitumor, and immunity-enhancement properties. It serves as a multifunctional compound that can be used in biomedical purposes [2] Another important property of CS is the nontoxicity and natural biodegradability. Recent studies revealed that there is a huge demand for synthesising polymer materials for flexible electronics; among them, polymers with a high dielectric constant play a vital role. A polymer blend that is based on poly(2-cyanoethyl vinyl ether) (CEPVA) and poly(methyl methacrylate) (PMMA) with relatively high dielectric constant has been reported [11]. From the electrolyte and electronic point of view, polymer blend fabrication with high dielectric constant is found to be very important. E design of polymer blends with high dielectric constant is of major importance from the viewpoint of flexible electronics and polymer electrolytes for battery and supercapacitor technology.
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