New Kinetic Theory for Absorption and Emission Rates of Radiation and New Equations for Lattice and Electronic Heat Capacities, Enthalpies and Entropies of Solids: Application to Copper

Abstract: New equations, which have analytical solutions, for lattice and electronic heat capacities, entropies and enthalpies at constant volume and constant pressure were derived by using kinetic theory, Kirchhoff and Stefan-Boltzmann laws and Wien radiation density equation. These equations were applied to the experimental constant volume heat capacity data of copper. The temperature ΘV corresponding to 3R/2 was found to be 78.4 K for copper. Copper shows the dimensionality crossover from 3 to 2 at about 80 K. The ΘV… Show more

“…A plot of C V /T versus T 2 should be a straight line with slope A and intercept γ and allows the determination of Debye temperature Θ D (0) through A = 12π 4 Rs/5Θ 3 D (0). In this study, the heat capacity, enthalpy and entropy equations proposed in [13] will be applied to the constant volume and constant pressure heat capacity data of tungsten. The temperature and dimension dependence of Debye temperature and the deviation from monotonicity will be explained.…”

New Kinetic Theory and New Equations for Lattice and Electronic Heat Capacities, Enthalpies and Entropies of Solids: Application to Tungsten

“…A plot of C V /T versus T 2 should be a straight line with slope A and intercept γ and allows the determination of Debye temperature Θ D (0) through A = 12π 4 Rs/5Θ 3 D (0). In this study, the heat capacity, enthalpy and entropy equations proposed in [13] will be applied to the constant volume and constant pressure heat capacity data of tungsten. The temperature and dimension dependence of Debye temperature and the deviation from monotonicity will be explained.…”

New Kinetic Theory and New Equations for Lattice and Electronic Heat Capacities, Enthalpies and Entropies of Solids: Application to Tungsten