• 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 casual 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 sub-atomic quantum system is a duplicate of the macro quantum system.  The two systems interact on a binary basis.
  • 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.
  • IT’S ALL ABOUT THE CODE THAT YOU START  WITH.
  • THE DESIGNER/CREATOR’S PROCESS : (recap).
  • 1ST: Write the code, for the upcoming big bang that will create another universe.  (One universe does not an infinity make.)
  • 2nd:  Write the code for the design and descent for all intended results as the event unfolds. ( One event does not an eternity make).
  • 3rd:  Set the event in motion. All things are triune, with binary interactives.
  • 4th:  Monitor, fine-tune, adjust, and select out on-going.
  • 5th: Use DESIGN AND DECENT as the process.  Write a separately coded blueprint for the consciousness of the known thought reposers.
  • 6th: It’s not the people, it’s the event.
  • 7th:  Harvesting new crops of known thought reposers was the intended result.
  • Quantum mechanics is the branch of physics relating to the very small. … At the scale of atoms and electrons, many of the equations of classical mechanics, which describe how things move at everyday sizes and speeds, cease to be useful. In classical mechanics, objects exist in a specific place at a specific time.
  • Quantum physics says that, until the moment of the measurement, the particles do not have a definite quantum spin but are in a superposition of possible states.
  • As soon as we measure the spin of Particle A, we know for sure the value we’ll get from measuring the spin of Particle B.
  • A new interpretation offers a consistent conceptual basis for nonrelativistic quantum mechanics. The Einstein-Podolsky-Rosen (EPRparadox is solved and the violation of Bell’s inequality is explained by maintaining realism, inductive inference and Einstein separability
  • Quantum Reality: Space, Time, and Entanglement - YouTube
  • REALITY DOESN’T KNOW WHAT IT IS UNTIL YOU MEASURE IT.
  • Information is contained in all particles.  Coded information was encoded at the time of particle creation.  The code of life is deterministic.
  • The quantum world communicates at speeds that are 10,000 times faster than the speed of light.  (maybe).
  • Information is exchanged through a giant entangled tapestry that threads the universe together. This is how entanglement works.  Quantum gravity holds the key to quantum entanglement.  
  • There are unsolved questions in physics, questions which lead us to consider the existence of structure beyond the Standard Model – in other words, preons.[1]* But additionally, reductionism concludes, by its very definition, that there should be fewer types of preons* than there are of quarks, leptons, and bosons.  gauge bosons are also made of equal quantities of logosons and primeons:  Electrons are made of primeons exclusively, giving them a charge of -6/6 (-1). Positrons are made of the exact opposite: 6 logosons, giving them a charge of +6/6 (+1).  Because of the various conservation laws of particle physics, a proton can only decay into lighter particles than itself. It cannot decay into a neutron or any other combination of three quarks.  Protons and neutrons consist of fundamental particles called quarks. A down quark within the neutron transforms into an up quark, changing the neutron into a proton (and changing the atomic element as a result).
  • * The preon proteins that are found in your brain are entangled with a form of preons that reside within the fabric of space/time. These space/time fabric preons are the facilitators for your ability to be conscious.Online Video – Physics says what?
  • quark is a tiny particle that makes up protons and neutrons. Atoms are made of protons, neutrons, and electrons. It was once thought that all three of those were fundamental particles, which cannot be broken up into anything smaller. … Only up and down quarks are found inside atoms of normal matter.
  • A neutron (udd) decays to a proton (uud), an electron, and an antineutrino. This is called neutron beta decay. (The term beta ray was used for electrons in nuclear decays because they didn’t know they were electrons!)
  • Quantum entanglement is a quantum mechanical phenomenon in which
  • the quantum states of two or more objects have to be described with reference to each other, even though the individual objects may be spatially separated.
  • It is possible to prepare two particles in a single quantum state such that when one is observed to be spin-up, the other one will always be observed to be spin-down and vice versa, this despite the fact that it is impossible to predict, according to quantum mechanics, which set of measurements will be observed.
Quantum electrodynamics (QED), quantum field theory of the interactions of charged particles with the electromagnetic field. … It describes mathematically not only all interactions of light with the matter but also those of charged particles with one another.
  • As a result, measurements performed on one system seem to be instantaneously influencing other systems entangled with it.
  • But quantum entanglement does not enable the transmission of classical information faster than the speed of light.
  • Quantum entanglement has applications in the emerging technologies of quantum computing and quantum cryptography and has been used to realize quantum teleportation experimentally.
  • At the same time, it prompts some of the more philosophically oriented discussions concerning quantum theory.
  • The correlations predicted by quantum mechanics, and observed in the experiment, reject the principle of local realism, which is that information about the state of a system should only be mediated by interactions in its immediate surroundings.
  • Different views of what is actually occurring in the process of quantum entanglement can be related to different interpretations of quantum mechanics.
  • In particle physics, the history of quantum field theory starts with its creation by Paul Dirac, when he attempted to quantize the electromagnetic field in the late 1920s. Major advances in the theory were made in the 1940s and 1950s, and led to the introduction of renormalized quantum electrodynamics (QED).
Modern physics - Wikipedia

Is Quantum Field Theory subject more tough than Quantum Mechanics, to study? - Quora

  • Perhaps it helps to make better sense of entanglement by dropping the naive notion of particles in favor of the fields of quantum field theory. Yes, unit (quantized) excitations of those fields manifest themselves as apparent particles (at least in flat spacetime). But it helps to remember that until a “particle” is observed through interaction, it does not even necessarily exist as a spatially localized entity (think, e.g., about two-slit experiments). So instead of entangled particles what we really have is entangled excitations of fields that are present in all of space and time. So given that the location of even a single particle is not well defined in the classical sense until it is observed, perhaps the notion that two such nonlocalized entities exhibit a correlation becomes a tad less mysterious and spooky.
  • The first formulation of a quantum theory describing radiation and matter interaction is attributed to British scientist Paul Dirac, who (during the 1920s) was able to compute the coefficient of spontaneous emission of an atom.[2]
  • Near the end of his life, Richard Feynman gave a series of lectures on QED intended for the lay public. These lectures were transcribed and published as Feynman (1985), QED: The Strange Theory of Light and Matter,[1] a classic non-mathematical exposition of QED from the point of view articulated below.
  • The key components of Feynman’s presentation of QED are three basic actions.[1]:85
  • What is Antimatter? - EWT
photon goes from one place and time to another place and time.
An electron goes from one place and time to another place and time.
 An electron emits or absorbs a photon at a certain place and time.