Browsing by Author "Alzahrani, Turki"
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Item Restricted Effect of Knowledge Sharing Behavior and Quality of Working Life on Organizational Citizenship Behavior among Nurses at King Fahad Hospital in Al Bahah(Saudi Digital Library, 2025) Alzahrani, Turki; Mahmoud, Hala; Ahmed, MaysaEffect of Knowledge Sharing Behavior and Quality of Working Life on Organizational Citizenship Behavior among Nurses at King Fahad Hospital in Al Bahah3 0Item Restricted Formulation and Characterization of Biopolymer for Solid-State Electrolytes(Saudi Digital Library, 2026) Alzahrani, Turki; Aravamudhan, Shyam; Rathnayake, HemaliFlammable organic electrolytes and narrow oxidative stability still prevent next-generation solid state lithium-ion batteries from using high-voltage cathodes with sustainable polymers. This dissertation addresses this problem by developing a bio-sourced, chitosan-based solid polymer electrolyte reinforced with a tannic-acid–lithium metal–organic framework (TALi). The TALi is novel because it combines phenolic anchoring sites from tannic acid with lithium coordination, creating both Li⁺ binding sites and mesoscale porosity in a single additive. Casting 4:1 chitosan:TALi films followed by controlled protonation produces dense 120 µm membranes with room-temperature ionic conductivity of 4.38 × 10⁻⁴ S cm⁻¹ about 12 times higher than pure chitosan. Conductivity increases to 1.90 × 10⁻³ S cm⁻¹ at 80 °C with an activation energy of 0.252 eV. Linear-sweep voltammetry shows practical stability up to ≈ 4.9 V vs Li/Li⁺ at 0.10 mA cm⁻². Li ‖ 4:1 film ‖ NMC 532 coin cells deliver 127 mAh g⁻¹ at C/20 (85% of liquid-electrolyte capacity) and retain 109 mAh g⁻¹ after 34 cycles with 93–95% coulombic efficiency, giving a fade rate of 0.06% per cycle. Rate tests show 56.8 mAh g⁻¹ at C/5 and 98% capacity recovery when returned to C/20. Spectroscopic and dielectric analyses show the high conductivity comes from dual Li⁺ transport pathways. These include segmental motion along protonated chitosan chains and vacancy-assisted hopping across catecholate sites in the MOF. Maxwell–Wagner polarization inside 50–200 nm pores also increases free-ion density. A percolation optimum near 20 wt% TALi balances conductivity, mechanical properties, and electrochemical window. This work demonstrates a practical approach toward safer, high-voltage, bio-derived electrolytes using scalable solution processing methods24 0