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Ranveer Kumar,
Gayatri Kumari,
Smita Kumari,
Rashmi Kumari,
A.K. Bhaskar,
- Research Scholar, Department of Physics, Patliputra University, Patna, Bihar, India
- Research Scholar, Department of Physics, Patliputra University, Patna, Bihar, India
- Assistant Professor, Department of Chemistry, College of Commerce, Arts and Science, Patna, Bihar, India
- Assistant Professor, Department of Zoology, College of Commerce, Arts and Science, Patna, Bihar, India
- Head of the department, Department of Physics, College of Commerce, Arts and Science, Patna, Bihar, India
Abstract
This article reformulates Microvita as a hybrid quantum excitation that interpolates continuously between fermionic and bosonic statistical behavior. A generalized operator algebra, a dynamical statistical order parameter, and a Lorentz-covariant field equation are used to frame Microvita as an effective unification scheme rather than a mere philosophical construct. The formalism predicts renormalization-group flow between infrared fermionic and ultraviolet bosonic limits, while numerical profiles suggest vacuum-energy smoothing and topological-defect suppression in the intermediate regime. To widen the scientific reach of the article, chemistry and zoology are linked to the model through coherent molecular organization, electron-pair transitions, enzyme-assisted reaction pathways, and biological coherence in structured living systems. Six MATLAB-ready figures are embedded directly into the paper to support journal presentation. The theory remains falsifiable through deviations from standard statistics in dense matter, early-universe physics, and high-coherence quantum media, and is presented here as a mathematically motivated step toward total unification.
Keywords: Microvita theory; hybrid statistics; fermion-boson unification; quantum field theory; statistical mechanics; vacuum structure; monopole suppression; chemical coherence; biological organization; MATLAB simulation
Ranveer Kumar, Gayatri Kumari, Smita Kumari, Rashmi Kumari, A.K. Bhaskar. Microvita as a Fermi-Boson Hybrid Quantum Excitation: A Statistical Pathway Toward Unified Physics, Chemistry, and Biological Organization. Journal of Modern Chemistry & Chemical Technology. 2026; 17(01):-.
Ranveer Kumar, Gayatri Kumari, Smita Kumari, Rashmi Kumari, A.K. Bhaskar. Microvita as a Fermi-Boson Hybrid Quantum Excitation: A Statistical Pathway Toward Unified Physics, Chemistry, and Biological Organization. Journal of Modern Chemistry & Chemical Technology. 2026; 17(01):-. Available from: https://journals.stmjournals.com/jomcct/article=2026/view=241424
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Journal of Modern Chemistry & Chemical Technology
| Volume | 17 |
| 01 | |
| Received | 30/03/2026 |
| Accepted | 01/04/2026 |
| Published | 29/04/2026 |
| Publication Time | 30 Days |
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