Scalar physics is the science of reality's hidden understructure. The electric, magnetic, and gravitational force fields are only the surface layer. Like waves upon the ocean, these forces arise from deeper fields known as potentials, which themselves arise from the primordial superpotential.
superpotential → potentials → force fields
Force fields derive from specific distortions or undulations in potentials:
- Vorticity in the magnetic vector potential [A] → magnetic field [B]
- Gradient in the scalar electric potential [V] → electric field [E]
- Gradient in the gravitational potential [P] → gravity field [G]
Similarly, potentials derive from specific distortions or undulations in the superpotential:
- Gradient in the superpotential [X] → magnetic vector potential [A]
- Change over time in the superpotential [X] → electric scalar potential [V]
But there also exist potential and superpotential fields that do not give rise to [E], [B], or [G] fields yet still provide certain exotic effects. Examples:
- gradient-free electric scalar potential [V]
- curl-free magnetic vector potential [A]
- gradient-free gravitational potential [P]
- gradient-free superpotential [X]
- unchanging superpotential [X]
Scalar physics concerns itself with potential and superpotential fields that do not necessarily give rise to magnetic or electric force fields, yet still have meaningful effects. It also points the way to a unified field theory between electricity, magnetism, and gravity. For instance, it may be possible to define the gravitational potential [P] in terms of [A] and thereby unify gravity with electromagnetism.
For more information, please read: A Brief Introduction to Scalar Physics (PDF)