Abstract

Biopolymer Gellan gum (GG) incorporated with ammonium iodide (NH₄I) salts and inorganic filler nano-TiO2 improved the ion transport facility in the salt-polymer matrix. The crystalline/amorphous nature of the membranes and the presence of n-TiO2 are evident from XRD analysis. The vibration modes corresponding to the characteristic functional groups and bonding interactions within the polymer matrix and incorporated filler materials present in the as-prepared membranes were analyzed using FTIR technique respectively. The ion transport parameters such as ionic conductivity (σ), diffusion coefficient (D), and mobility (μ), were studied using Ac impedance, transference number measurement, and FTIR deconvolution. The biopolymer membrane with the composition, 1 g GG: 0.3 M.wt% of NH4I (GGAI-3) shows the highest ionic conductivity of 2.65 ± 0.03×10−3 S/cm and on addition of 0.1 M.wt% of n-TiO2 (GGAIT-1) the increase in ionic conductivity of 4.07 ± 0.02×10−2 S/cm was observed. The H¹NMR studies help in understanding the mobility of charge carriers upon their chemical shifts. The glass transition temperature values of the as-prepared membranes were determined using DSC studies. The morphological change on the surface of the GG polymer membrane due to the addition of NH4I and n-TiO2 were analyzed using the SEM technique. The thermal, mechanical, and chemical stability of the highest ion-conducting biopolymer and composite polymer membranes were assessed using TGA, mechanical stability tests, and chemical stability tests. The IEC test exhibits the number of exchangeable ions in the polymer matrix. Utilizing the GGAI-3 and GGAIT-1 membranes as electrolytes, proton batteries were constructed and observed to have the pseudocapacitive behaviour; as the electrodes experience surface limited redox reaction at the electrode-electrolyte interface. The PEMFC cell using the GGAI- 3 and GGAIT-1 as proton exchange membrane exhibits the OCV of 646 mV and 682 mV respectively. Their performances were analyzed using the I-V polarization curve resulted with the power density of 0.14 mW/cm2and 0.34 mW/cm2 respectively.

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