Description

Heat Transfer with Fractional Derivatives explores an innovative approach to modeling and analyzing heat transfer phenomena using fractional calculus. Traditional heat transfer analyses are based on integer-order derivatives, but fractional derivatives offer a more nuanced and accurate representation of heat conduction in complex materials and geometries.

In this research, fractional calculus is employed to describe the temporal and spatial behavior of heat conduction processes, considering the memory effects and non-local behavior exhibited by certain materials. The fractional heat transfer equations are solved using advanced numerical methods to predict temperature distributions and heat fluxes in various systems.

This novel approach has significant implications for a wide range of applications, including materials processing, thermal management in electronics, energy storage, and geothermal systems. The use of fractional derivatives allows for a more precise understanding of heat transfer behaviors in situations involving fractal-like structures or non-integer scaling laws.

By leveraging fractional calculus in heat transfer analysis, engineers and researchers gain a powerful tool to optimize thermal designs and improve energy efficiency. Ultimately, this research contributes to advancements in heat transfer science and technology, fostering innovative solutions for various engineering and scientific domains.