Difference between revisions of "Bee-Theory"
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Contact us. Thanks for your help.<BR> | Contact us. Thanks for your help.<BR> | ||
− | Summary in | + | Summary in english / first mathematic review : |
− | [[File:20231226 BeeTheory v2.pdf]] | + | [[File:20231226 BeeTheory v2 EN.pdf]] |
Résumé en français / première formalisation mathématique : | Résumé en français / première formalisation mathématique : |
Revision as of 15:33, 26 December 2023
Bee-Theory project is studying a theory on gravity.
It assumes that gravity is created by the summation of two particules wavefunction.
Summation of two radial exp-x term of the Schroedinger equation create an attractive force with potential 1/D and force in 1/D2
Project was created in 2015. Formalized in 2016.
Mathematical theory was writen with ChatGPT in 2023, with the Laplacien in spherical coordinates of two particules.
We are looking for advanced contacts that could juge the theory.
Contact us. Thanks for your help.
Summary in english / first mathematic review : File:20231226 BeeTheory v2 EN.pdf
Résumé en français / première formalisation mathématique : File:20231226 BeeTheory v2.pdf
Bee-Theory basic presentation :
File:Bee-Theory v3-6.pdf
Web Site
www.BeeTheory.com
A novel approach to understanding gravitational forces
The BeeTheory project proposes a novel approach to understanding gravitational forces through ondular quantum mathematics. The current gravitational models, Newtonian physics and Einstein's theory of general relativity, have been instrumental but still lack a unifying explanation of why gravity exists. BeeTheory attempts to fill this gap, introducing a non-graviton-based model for gravity.
Ondular Functions and Particle Interaction BeeTheory's foundation lies in ondular functions to describe particles. Unlike classical theories that rely on gravitons or mass-induced space-time curves, BeeTheory suggests that peaks of ondular functions between two particles are proximal compared to the average position of individual particles. This closeness generates movement in each particle, directing them toward each other, hence, the gravitational attraction.
Breakthrough in Sub-Scale Models The current gravitational equations work excellently on a macro-scale but falter at the sub-scale. BeeTheory provides a framework for understanding the gravitational interactions at smaller scales. Questions like why gravity cannot be blocked, whether anti-gravity engines could exist, or the feasibility of creating gravity artificially are approached with a new lens through this theory.
Beyond Classical and Relativistic Views While Newton focused on the inverse-square law and Einstein curved space-time to explain gravity, BeeTheory moves a step further by potentially answering why this force exists. The dual nature of matter—particles and waves—converges into a single theory here, elucidating the 'how' behind gravity.
Computational Modeling and Real-world Implications Advanced numerical simulations and direct analysis of gravitational fields have been performed using the ondular gravitational model. This includes the study of gravitational waves based on individual ondular function velocities. The wave equation in three dimensions governs the dispersion forces that influence particle distribution. BeeTheory has the potential to shake the foundations of fundamental science. The wave propagation of individual particles according to this theory could become the cornerstone of interaction forces, thereby having implications for everything from astrophysics to engineering.
Addressing Phenomena: Hidden Mass and Plasma Jets The theory presents a compelling explanation for phenomena like hidden mass in the universe and pulsar-generated massive plasma jets. Its robust mathematical framework could serve as a groundbreaking tool for untangling unexplained cosmic phenomena.
Open Questions and Further Research Although promising, BeeTheory is still a subject of rigorous validation. Competing theories, including modified gravity theories and quantum gravity models, have yet to be reconciled or dismissed in light of this new approach. Plus, how BeeTheory aligns with thermodynamics and other fundamental principles remains to be examined.
In conclusion, BeeTheory posits an innovative gravitational model that relies on ondular quantum mathematics to explain gravity, moving beyond the limitations and unexplained facets of both Newtonian and Einsteinian models. It opens new avenues for understanding not just gravity but potentially other fundamental interactions as well.
Advancing the Frontiers of Gravitational Science with BeeTheory
BeeTheory goes beyond conventional wisdom by leveraging ondular quantum mechanics to dissect gravity's very essence. This disruptive framework presents a cogent answer to long-standing questions concerning the structure and nature of gravitational forces. It also delves into the limitations of existing gravitational models, particularly where classical theories stumble in the realm of quantum mechanics. BeeTheory transcends these barriers, offering a holistic view of gravitational forces that unifies wave-particle duality in a unique way.
By operationalizing these advanced mathematical models, BeeTheory stands as a beacon for emerging theories in gravitational physics. The project has initiated a paradigm shift, drawing increased attention from academics, researchers, and industry experts interested in redefining our understanding of gravitational interactions. Through BeeTheory, the complex interplay of particle behavior and wave mechanics is elucidated, shedding light on phenomena such as dark matter, black holes, and even the underlying forces in advanced engineering applications.
Therefore, BeeTheory not only has profound implications for gravitational physics but also paves the way for innovative applications in various scientific and engineering disciplines. It promises to be a cornerstone in the future of theoretical and applied physics, serving as a potent tool for both research and practical applications.
Mots clés:
projet, gravité, théorie, ondulaire, particules, mathématiques quantiques, forces gravitationnelles, modèles gravitationnels, physique newtonienne, relativité générale, gravitons, courbure de l'espace-temps, équations gravitationnelles, échelle subatomique, interactions gravitationnelles, moteurs anti-gravité, gravité artificielle, dualité onde-particule, simulations numériques, champs gravitationnels, ondulations, ondular, ondulaire, ondular functions, dispersion des forces, astrophysique, ingénierie, masse cachée, jets de plasma, thermodynamique, principes fondamentaux, interactions fondamentales.
Keywords:
project, gravity, theory, ondular, particles, quantum mathematics, gravitational forces, gravitational models, Newtonian physics, general relativity, gravitons, space-time curvature, gravitational equations, subatomic scale, gravitational interactions, anti-gravity engines, artificial gravity, wave-particle duality, numerical simulations, gravitational fields, ripples, ondular functions, force dispersion, astrophysics, engineering, hidden mass, plasma jets, thermodynamics, fundamental principles, fundamental interactions.