Application of green energy and environment-friendly decorative composite materials by using kinetic model with Sodium Alanate Nano carbon particle for building technologies

Hydrogen energy is the main key point to make the long-term energy be secure. The unit of an economic system is completed by hydrogen generation, storage, transit, and use. Nonetheless, its storage strategies have clashed with applications that need hydrogen on board. The zero-energy idea was designed to assist in the development of energy policies with the goal of developing and constructing sustainable communities and structures. The higher the scale, the more plausible a zero-energy hydrogen economy is. H₂ and fuel cell storage work together optimally to reduce uncertainty. The potential systems based on Sodium Alanate (SA) under the kinetic model was motivated by the extensive use and intriguing features of diverse silicon carbon nanomaterials. The electrical characteristics, structural stability, and adsorption energies of hydrogen molecules are investigated. Sodium Alanate is used in hydrogen gas release to investigate its feasibility. Hydrogen sorption procedure inside a storage container is modeled based on hydrogen transport equations, generated heat transfers and kinetic formulas. In this research, a numerical solution is created and verified using previously acquired empirical findings. This study defines and optimizes the gravimetric H₂ storage potential on the basis of SA using numerical simulation data.