Research Interests¶
My research focuses on mechanical and continuum-based descriptions of physical phenomena, with particular emphasis on neutrinos, fundamental interactions, and statistical physics. This work is conducted independently and includes both theoretical development and numerical modeling.
Neutrino Mechanics Theory¶
I study mechanical models in which neutrinos are treated as physical entities possessing translational and rotational motion. Within this framework, neutrinos are modeled as a continuous medium that may underlie gravitational, electromagnetic, and nuclear phenomena. The goal is to explore whether classical mechanical principles can provide alternative insight into fundamental interactions.
Statistical Physics and Entropy¶
My work includes extensions of classical kinetic theory and entropy formulations, with emphasis on mechanical interpretations of equilibrium distributions and the heat capacity ratio. This research involves analytical studies related to the Maxwell–Boltzmann distribution, entropy production, and transport processes.
Molecular and Neutrino Wave Analogies¶
I investigate analogies between acoustic wave propagation in gases and wave phenomena in other physical systems. These analogies are used to develop mechanical insight into wave speed, energy transport, and mass estimation methods, including applications to neutrino-related problems.
Engine Combustion Simulation¶
I have developed numerical simulation codes for internal combustion engine systems involving four-stroke engine cycles, engine control algorithms, and combustion modeling. These simulations are based on chemical stoichiometry, thermodynamics, and engine mechanics, and were applied to misfire detection and control problems.
Rotor Dynamics Simulation¶
I have developed rotor–bearing dynamic simulation codes for turbocharger design and optimization. The rotor–bearing system is modeled with relevant dynamic forces, including gyroscopic effects, to account for the extremely high rotational speeds encountered in turbocharger applications.