Title : A projection-geometric reinterpretation of subatomic matter, particles, fields, and interactions: Toward b-chem quantum chemical physics
Abstract:
Subatomic matter is usually described through particles, fields, interactions, quantum numbers, scattering behavior, and experimentally measurable observables. This presentation introduces a projection-geometric reinterpretation of subatomic matter, particles, fields, and interactions, moving toward B-Chem Quantum Chemical Physics. The framework does not propose a new particle, new force, or replacement physical law; rather, it reformulates established subatomic and atomic entities as layered Bansal sector objects whose internal sectors project into observable physical quantities.
A central claim of the model is that a physical object contains not only active and directly measurable sectors, but also silent sectors: admissible structural components that may remain hidden, inactive, non-dominant, or condition-dependent under a given measurement or experimental context. Thus, an observed fermion, boson, proton, neutron, nucleus, electron, atom, ion, conductor, or bond is not represented only by its visible output, but by a fuller sector structure containing active, silent, known, latent, transport, field, binding, decay, and response components.
The model is developed through Bansal representations of fermions, quarks, leptons, bosons, protons, neutrons, nuclei, electrons, atoms, and bonding structures. These objects are expressed through coordinated sectors such as particle-core structure, electromagnetic tensor behavior, charge-current flow, color/QCD curvature, wave and resonance response, stress-energy and binding, quantum-field/Fock-space behavior, scattering, decay, hydrodynamic transport, magnetohydrodynamic response, and thermodynamic relaxation.
The framework also bridges electrical engineering, chemistry, and quantum physics through the example of electron flow in conductors such as copper and aluminium, and short-circuit model. From the electrical-engineering view, an imposed current gives a charge-equivalent electron-count projection. Therefore, for the same current and time, copper and aluminium give the same current-defined electron-number readout. From the chemistry/material view, however, Cu and Al differ in electronic configuration, bonding environment, conductivity, resistance, scattering, heating, and drift response. From the quantum-physics view, these differences arise from the underlying electron, atomic, field, orbital, and transport sectors rather than from the current-count projection alone.
In this interpretation, chemistry becomes a continuation of quantum subatomic structure: atoms, ions, orbitals, bonds, spectra, conductors, and reactions are higher-level projections of particle-field-sector organization. The aim of the talk is to present the Bansal projection-geometric model of subatomic physics as a unifying language connecting quantum particles and fields to atomic structure, chemical behavior, and electrical transport, thereby motivating B-Chem Quantum Chemical Physics as a physics-first framework for matter and interaction.
