Every symmetry of physics laws leads to a conservation law, and every conservation law arises from a symmetry in the laws of physics.
Symmetry is the causal structure built into the creation module. The creation module has a two-way arrow of time that is built into it. All current information is always passed back into the versatile storage unit. These informational totals can’t be changed or deleted.
The closed subatomic quantum system is a duplicate of the macro quantum system. The two systems interact on a binary basis.
The triune combined functions of consciousness, quantum gravity, and quantum entanglement act as one from the underside of the fabric of space-time.
Symmetry is the causal structure built into the creation module. The creation module has a two-way arrow of time that is built into it. All current information is always passed back into the versatile storage unit. These informational totals can’t be changed or deleted.
The closed subatomic quantum system is a duplicate of the macro quantum system. The two systems interact on a binary basis.
CONSCIOUSNESS CREATES SPACE/TIME.
1. CLASSICAL PHYSICS (FROM THE RENAISSANCE, THROUGH THE BEGINNING OF THE 20TH CENTURY).
2. MODERN PHYSICS (AFTER THAT, TO NOW).
THE LAW THAT CONTROLS ALL PARTICLE INTERACTIONS IS THIS:
ALL THINGS ARE TRIUNE, WITH BINARY INTERACTIVES. THIS IS THE LINKAGE BETWEEN MATTER AND FORCE CARRYING PARTICLES. THE LINKAGE BETWEEN THE PARTICLE ZOO IS CONTROLLED BY FERMIONS AND BOSONS.
THE REALITY OF HOW LIFE FORMS CAME ABOUT ON THIS REMOTE BLUE MARBLE IS THIS: THE EVENT ORIGINATOR WROTE THE CODE, PRODUCED THE BLUEPRINT, AND USED AN EVOLVEMENT PROCESS TO OBTAIN THE REQUISITE RESULT. IT’S ALL JUST A BINARY SOFTWARE PROGRAM.
ore the turn of the 19th Century, physics concentrated on the study of mechanics, light, sound and wave motion, heat and thermodynamics and electromagnetism.
A. Classical fields studied, include:
Acoustics: (sound and sound waves).
Astronomy: (The study of space, including the planets, stars, galaxies, and the universe.)
Chemical Physics: (The physics of chemical systems. Understanding the physics of a molecule through a biological system.)
Computational Physics: (The application of numerical methods to solve physical problems.)
Electronics: (The study of the flow of electrons, generally in a circuit.)
Electromagnetism: (The study of electrical and magnetic fields.)
Fluid Dynamics/ Fluid Mechanics: (The study of the physical properties of fluids and gases.)
Geophysics: (Study of the physical properties of the Earth.)
Mathematical Physics: (Using math methods to solve physics problems.)
Mechanics: (The study of the motion of bodies, referentially.)
Optics/Light Physics: (The physical properties of light.)
Thermodynamics: (The physics of heat.)
B. Modern Physics: Study of the atom, and its component parts. Relativity, cosmology and space exploration. Mesoscopic physics.
Some of the fields, are:
Astrophysics: The study of the physical properties of objects in space.
Atomic physics: The study of atoms. (the electron properties of the atom.)
Biophysics: The study of physics in living systems. Topics can include bio-electronics, nano-medicine, quantum biology, enzyme kinetics, and radiology.
Chaos: How initial small changes in a system greatly affect outcomes. Chaos theory is an element of quantum physics.
Cosmology: The study of the universe as a whole, from the big bang until now.
High Energy Physics: Study of extremely high energy systems, within particle physics.
High-Pressure Physics: High-pressure systems, usually within fluid dynamics.
Laser Physics: The physical properties of lasers.
Molecular Physics: The physical properties of molecules.
Nanotechnology: Building circuits and machines from single molecules and atoms.
Nuclear Physics: The physical properties of the atomic nucleus.
Particle Physics: Fundamental particles and the forces of their interaction.
Plasma Physics: The study of matter in the plaza phase.
Relativity: The properties of systems of the theory of relativity that move near the speed of light.
String Theory/Superstring Theory: The study of the theory that all fundamental particles are vibrations of one-dimensional strings of energy, in a higher-dimensional universe.
Quantum Field Theory: The application of quantum physics to fields, including the fundamental forces of the universe.
Quantum Gravity: The application of quantum physics to gravity and unification of gravity with the other fundamental particle interactions.
Quantum Mechanics/Quantum physics: The study of science where the smallest discrete values, or quanta, of matter and energy, become relevant.
Quantum optics: The application of quantum physics to light.
Quantum Electrodynamics: The study of how electrons and photons interact at the quantum mechanical level.