Differences in Water Dynamics between the Hydrated Chitin and Hydrated Chitosan Determined by Quasi-Elastic Neutron Scattering

Proton-transfer mechanisms and hydration states were investigated in chitin films possessing the functionality of fuel-cell electrolytes. The absolute hydration number per chitin molecule (N) as a function of relative humidity (RH) was determined from the OH stretching bands of H2O molecules, and the proton conductivity was found to enhance above N = 2 (80%RH). The FIR spectrum at 500–900 cm−1 for 20%RH (N < 1) together with first-principles calculations clearly shows that the w1 site has the same hydration strength as the w2 site. The molecular dynamics simulations for N = 2 demonstrate that H2O molecules with tiny fluctuations are localized on w1 and w2, and the hydrogen-bond (HB) network is formed via the CH2OH group of chitin molecules. Shrinkage of the O–O distance (dOO), which synchronizes with the barrier height, is required for proton transfer from H3O+ to adjacent CH2OH groups or H2O molecules. Nevertheless, dOO is hardly modulated for N = 2 because H2O molecules are strongly constrained on w1 and w2, and therefore, the transfer probability becomes small. For N = 3, novel HBs emerged between the additional H2O molecules broadly distributed on the w3 site and H2O molecules on w1 and w2. The transfer probability is enhanced because large fluctuations and diffusions in the whole H2O molecule yield large modulations of dOO. Consequently, long-range proton hopping is driven by the Zundel-type protonated hydrates in the water network.

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The isotopic effect of deuteration on the conductive properties of chitosan films

Uali,

Aslanbek

2024

Preprint

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Chitosan biopolymer has gained attention due to its distinctive chemical and environmental characteristics, such as its biocompatibility and biodegradability, ability to form fibres/films, and ionic conductivity. Its functional groups offer various interactions, including cross-linking, intermolecular hydrogen bonding, complex formation, and chelation. All this makes chitosan one of the most extensively used platforms for developing biomedical and pharmaceutical applications, agriculture, water treatment, environmental protection, energy storage systems and many others. This study examined the structure and properties of protonated and partially deuterated chitosan films. Herein, we present the chitosan films prepared from their acidic solutions by casting. By employing spectroscopic techniques, it was shown that, firstly, there is a partial deuteration of chitosan polymer films; secondly, the higher the content of D2O used for deuteration, the lower the conductivity of CS films, thus, the more apparent kinetic isotope effect arising from hydrogen-deuterium exchange in the polymer structure. The conductive properties were evaluated by using chronoamperometry and a four-probe approach. This work provides a simple way to shed light on the probable semi-classical nature of the mechanism underlying the conductive properties of chitosan.

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Differences in Water Dynamics between the Hydrated Chitin and Hydrated Chitosan Determined by Quasi-Elastic Neutron Scattering

Cited by 3 publications

References 30 publications

Power generation characteristics and optimum alcohol concentration in bio-direct alcohol fuel cell using chitin family electrolyte

Power generation characteristics and optimum alcohol concentration in bio-direct alcohol fuel cell using chitin family electrolyte

Proton transfer driven by the fluctuation of water molecules in chitin film

The isotopic effect of deuteration on the conductive properties of chitosan films

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