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Probing the dynamics of water in chitosan polymer films by dielectric spectroscopy
Author(s) -
Murugaraj P.,
Mainwaring D. E.,
Tonkin D. C.,
Al Kobaisi M.
Publication year - 2010
Publication title -
journal of applied polymer science
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.575
H-Index - 166
eISSN - 1097-4628
pISSN - 0021-8995
DOI - 10.1002/app.33163
Subject(s) - dielectric , dielectric spectroscopy , relaxation (psychology) , materials science , dielectric loss , conductivity , polymer , spectroscopy , chemical physics , aqueous solution , polymer chemistry , chemical engineering , composite material , chemistry , physics , optoelectronics , psychology , social psychology , electrode , quantum mechanics , engineering , electrochemistry
Chitosan biopolymers are increasingly being used in advanced biomedical applications, where aqueous interactions profoundly influence their physical properties and also their in vivo biomolecular and cellular activity. Here, hydration of chitosan films is studied by dielectric spectroscopy in a conventional constraining plate configuration and compared with free standing films. Film hydration proceeds by an initial water uptake followed by a spontaneous dehydration (deswelling) even in saturated atmospheres. At water contents above a critical value, ∼ 9.5 wt % a dielectric loss resonance peak (β wet ) arises from relaxation of evolving chitosan–water complexes, below this value insufficient interchain space for oscillation of these complexes prevents β wet appearing. The β wet frequency was related to water content by a power law with the frequency changing by ∼ 3 orders of magnitude. Importantly the scaling exponents (slopes) differed significantly for unconstrained (free standing) and volume constrained films indicating the effect of internal stresses in constrained films. Both dielectric and conductivity behavior were influenced by internal constraining stresses affecting both oscillatory motion and charge mobility. In biomedical devices, biopolymers may be free standing, surface adhered, or enclosed structures imposing different internal stresses on polymer chains and the mobility of their segments. Dielectric spectroscopy can examine these influences on dielectric and electrical characteristics, which play a critical role in biomolecular interactions. © 2010 Wiley Periodicals, Inc. J Appl Polym Sci, 2011