Microvita: A New Hybrid Particle Bridging the Fermionic and Bosonic Domains in Particle Physics

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Year : 2026 | Volume : 15 | 01 | Page :
    By

    Ranveer Kumar,

  • A.K. Bhaskar,

  1. Research Scholar, Department of Physics, Patliputra University, Patna-20., Bihar, India
  2. Head of the department, Department of Physics, College of Commerce, Arts and Science, Patna-20., Bihar, India

Abstract

In particle physics, the established classification of particles into fermions and bosons—obeying Fermi-Dirac and Bose-Einstein statistics, respectively—has shaped theoretical and experimental frameworks for nearly a century. This study introduces ‘Microvita’, a novel theoretical particle that exhibits hybrid characteristics modulated by a continuous parameter α ∈ [0,1]. Through this parameter, Microvita interpolates between bosonic and fermionic behavior in terms of spin, statistical distributions, and operator algebra. We explore the foundational algebra underlying these particles and propose generalized commutation relations that recover standard fermion and boson limits as α approaches 0 or 1. Using MATLAB simulations, we visualize statistical transitions, phase dynamics, and quantum coherence properties associated with Microvita. Applications range from early universe baryogenesis and CP-violation models to quantum computing frameworks and possible biological quantum coherence. A mathematical model supporting Microvita’s hybrid symmetry behavior is developed and key equations, graphs, and operator behavior are discussed in detail. The concept holds potential for enhancing grand unified theories (GUTs), advancing quantum information science, and even providing insight into cognitive processes if coherence is preserved in hybrid systems. This work proposes Microvita as a foundational extension to the Standard Model by integrating symmetry, algebra, and hybrid quantum statistics into a unified framework supported by numerical analysis and visual models. [4]

Keywords: Microvita, hybrid particle, fermion-boson unification, quantum field theory, spin interpolation, baryogenesis, CP violation, MATLAB simulation

How to cite this article:
Ranveer Kumar, A.K. Bhaskar. Microvita: A New Hybrid Particle Bridging the Fermionic and Bosonic Domains in Particle Physics. Research & Reviews : Journal of Physics. 2025; 15(01):-.
How to cite this URL:
Ranveer Kumar, A.K. Bhaskar. Microvita: A New Hybrid Particle Bridging the Fermionic and Bosonic Domains in Particle Physics. Research & Reviews : Journal of Physics. 2025; 15(01):-. Available from: https://journals.stmjournals.com/rrjophy/article=2025/view=233350


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Ahead of Print Subscription Review Article
Volume 15
01
Received 06/11/2025
Accepted 13/11/2025
Published 02/12/2025
Publication Time 26 Days
150

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