| ai.viXra.org > Thermodynamics and Energy > 2506 |
|
 |
| ai.viXra.org > Thermodynamics and Energy > 2506 |
|
|
[3] ai.viXra.org:2506.0058 [pdf] submitted on 2025-06-14 23:41:34
Authors: Vivek Kumar
Comments: 6 Pages. https://zenodo.org/records/15653592
This paper proposes a novel passive mechanism for entropy gradient formation in a collisionless gas system using a preconfigured timer-based gating approach. Unlike the Maxwell’s Demon paradigm, this model requires no sensing, memory, or intelligent control. Simulations demonstrate separation in both flat and exponentially expanding spacetime, with the latter showing natural thermodynamic sorting. Mathematical modeling with the Vlasov equation supports the entropy differential outcome.
Category: Thermodynamics and Energy
[2] ai.viXra.org:2506.0057 [pdf] submitted on 2025-06-14 23:40:33
Authors: Vivek Kumar
Comments: 3 Pages. https://doi.org/10.5281/zenodo.15656032
This paper presents a numerical and visual study building upon a prior theoretical frame work that demonstrated entropy gradient formation in a collisionless, expanding gas system without requiring active feedback or measurement. Using the Vlasov formalism and scale factor-based dynamics, I simulate entropy redistribution and confirm spatial asymmetry as a result of velocity-based passive sorting.
Category: Thermodynamics and Energy
[1] ai.viXra.org:2506.0007 [pdf] submitted on 2025-06-02 02:22:55
Authors: Chase Bruttomesso
Comments: 26 Pages.
This paper presents a field-based reinterpretation of heat within the Eonix Theoryframework, challenging the conventional notion that heat is a form of energy linked to molecular motion. Eonix Theory models all physical phenomena as emergent from acontinuous, compressible scalar field [1, 2]. Here, heat is reconceptualized as a manifestation of ψ-field energy redistribution across molecular systems, rather than as kineticactivity or independent thermodynamic energy [5, 14, 15, 17].We demonstrate that temperature corresponds to the expansion or compression ofmolecular ψ-fields, and that heat transfer arises from two primary mechanisms: directfield-to-field interaction and radiation-to-field induction [2, 5]. Simulations of boiling,condensation, and freezing under varying environmental pressures validate the role ofψ-field pressure gradients and recoil dynamics in phase transitions [1, 4]. Infrared spectral signatures are modeled as the byproduct of ψ-field stabilization, with distinct spectral fingerprints predicted for each phase change [18, 19].A complete experimental protocol is proposed, enabling empirical verification of the ψ-field recoil hypothesis through infrared spectroscopy in controlled vacuum and pressure environments. By framing heat as a ψ-field process driven by field density gradients and emission recoil, this work provides a unified model that aligns thermal behavior with gravitational, quantum, and energetic principles of Eonix Theory [2, 1, 4].
Category: Thermodynamics and Energy