Author(s)

Tomofumi Miyashita

Miyashita Clinic, Mitsuya-kita, Yodogawa-ku, Osaka, Japan.

Bell’s non-locality theorem can be understood in terms of classical thermodynamics, which is already considered to be a complete field. However, inconsistencies in classical thermodynamics have been discovered in the area of solid-oxide fuel cells (SOFCs). The use of samarium-doped ceria electrolytes in SOFCs lowers the open-circuit voltage (OCV) to less than the Nernst voltage. This low OCV has been explained by Wagner’s equation, which is based on chemical equilibrium theory. However, Wagner’s equation is insufficient to explain the low OCV, which should be explained by fluctuation and dissipation theorems. Considering the separation of the Boltzmann distribution and Maxwell’s demon, only carrier species with sufficient energy to overcome the activation energy can contribute to current conduction, as determined by incorporating different constants into the definitions of the chemical and electrical potentials. Then, an energy loss equal to the activation energy will occur because of the interactions between ions and electrons. This energy loss means that an additional thermodynamic law based on an advanced model of Maxwell’s demon is needed. In this report, the zero-point energy can be explained by this additional ther-modynamic law, as can Bell’s non-locality theorem.

Wagner’s Equation, Fluctuation and Dissipation Theory, Boltzmann Distribution, Maxwell’s Demon, Additional Thermodynamic Law

Miyashita, T. (2017) Bell’s Non-Locality Theorem Can Be Understood in Terms of Classical Thermodynamics. Journal of Modern Physics, 8, 87-98. doi: 10.4236/jmp.2017.81008.