(Digital Presentation) Biogenic Electrodes for Low-Temperature Solid Oxide Fuel Cells

Abstract

Biogenic Electrodes for Low-Temperature Solid Oxide Fuel Cells Jyoti Bhattacharjee, Subhasis Roy* Department of Chemical Engineering, University of Calcutta, 92 A. P. C. Road, Kolkata-700009, India * Email: subhasis1093@gmail.com/srchemengg@caluniv.ac.in : Solid oxide fuel cells (SOFCs) are potential energy-generation devices. They operate at hightemperatures, typically between 800°C-1000°C, limiting their utility. The primary challengein developing these fuel cells is synthesizing strong biogenic electrodes that function at lowtemperatures, maintaining high performance. This experimental study examines how eco-friendly,facile, and novel techniques for synthesis can be used to make robust, effective, and affordableelectrodes for low-temperature recyclable SOFCs (LT-SOFC). A green approachwas implemented by using biomass waste and biochar, specifically coconut shells and ricehusks, as raw materials. The synthesis comprised the hydrothermal carbonization of biomassprecursors, such as lignocellulosic nanostructures, and carbon nanotubes under controlledconditions, followed by activation with potassium hydroxide(KOH). The resulting electrodeshad a large surface area, catalytic oxygen reduction, excellent conductivity, and sufficientelectrochemical performance. The efficacy of the biomass-derived electrodes was enhancedby employing transition metal oxides as electrocatalysts, such as nickel oxide(NiO) andcobalt oxide(Co3O4). The morphology and elemental composition of the electrode materialwere studied using the scanning electron microscope(SEM) and energy-dispersive X-rayspectroscopy(EDS). Electrochemical impedance spectroscopy(EIS)was used to examine theelectrochemical properties of cell electrolytes. Findings demonstrated that the hydrothermalstrategy led to the formation of homogeneous and porous electrode structures with highgalvanic activity. The biodegradable LT-SOFC stack achieved an optimal power density of346mW/cm2 at around 550°C, indicating a substantial increase over previous experiments.Our results have significant economic consequences for the expansion of sustainable andrenewable energy innovations in industry and nanotechnology, providing auxiliary power inautomobiles and hydrogen generation. Greenhouse gas emissions and carbon footprint can bediminished by using biomass waste streams as feedstocks, reducing the need for fossil fuels.The outcomes of this research provide important insights into the development, challenges,and future possibilities of biomass-derived electrodes, and minimal temperature electrolytesfor stable SOFCs. Keywords: Biomass-derived; carbon footprint; electrochemical efficiency; green energy; low-temperature solid oxide fuel cells; nanotubes.