TITLE:
Quantization Heat Capacity Equations at Constant Volume According to Energy Levels and Planck Constant
AUTHORS:
Daekyoum Kim, Youngpak Lee
KEYWORDS:
Statistical Thermodynamics, Quantized Heat Capacity of Metal, Five Energy Levels, Binomial Theorem, Boltzmann Constants, Planck Constant
JOURNAL NAME:
American Journal of Analytical Chemistry,
Vol.9 No.8,
August
3,
2018
ABSTRACT: The quantization thermal excitation isotherms based on the maximum triad spin number (G) of each energy level for metal cluster were derived as a function of temperature by expanding the binomial theorems according to energy levels. From them the quantized geometric mean heat capacity equations are expressed in sequence. Among them the five quantized geometric heat capacity equations, fit the best to the experimental heat capacity data of metal atoms at constant pressure. In the derivations we assume that the triad spin composed of an electron, its proton and its neutron in a metal cluster become a basic unit of thermal excitation. Boltzmann constant (kB) is found to be an average specific heat of an energy level in a metal cluster. And then the constant (kK) is found to be an average specific heat of a photon in a metal cluster. The core triad spin made of free neutrons may exist as the second one additional energy level. The energy levels are grouped according to the forms of four spins throughout two axes. Planck constant is theoretically obtained with the ratio of the internal energy of metal (U) to total isotherm number (N) through Equipartition theorem.