Soumendra Nath Thakur
March 18, 2025
In the framework of Extended Classical Mechanics (ECM), the universal total energy, denoted as Eₜₒₜₐₗᴜₙᵢᵥ can be understood as a dynamic balance of energy components that govern the fundamental interactions of the universe. At any given moment, this energy is composed of two primary elements: the universal potential energy, PEᴜₙᵢᵥ, which accounts for the energy stored in gravitational interactions, and the displaced energy-mass component, which influences the system’s effective mass and motion.
Within this perspective, the concept of negative apparent mass, -Mᵃᵖᵖ, emerges as a key factor in determining the overall energy distribution. It represents an energy-mass equivalence that effectively reduces the observable mass-energy of a system while maintaining gravitational coherence. This negative apparent mass acts analogously to a buoyant force in a fluid medium, where an object appears to lose weight due to the displacement of the surrounding medium’s energy density.
From an ECM standpoint, the universal kinetic energy, KEᴜₙᵢᵥ complements the potential energy to establish a complete energy framework. The variations in apparent mass contribute directly to shifts in the effective energy balance, influencing the dynamic behaviour of celestial structures and fundamental cosmological events. This interplay between gravitational potential, displaced energy-mass, and effective kinetic contributions provides a refined understanding of energy interactions beyond conventional models.
By applying these principles to the early universe, ECM reinterprets the force-energy-gravity state at the Big Bang event without relying on traditional vacuum energy fluctuations. Instead, the emergence of universal energy structures can be attributed to the redistribution of effective mass-energy states, where the role of negative apparent mass plays a crucial part in shaping early gravitational and energetic conditions.
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