QUANTUM RARITIES. (Chapter 5. Part 1.)

From de book: Quantum Mysticism. THE SPIRITUALITY OF QUANTUM PHYSICS. Second Edition 2021.

Author:         Luis Eduardo Sierra S.

President of Universal Alliance – Director ARIEL Magazine - Senior Instructor at the Spiritual University in Colombia.

Chapter 5 – Part 1

QUANTUM RARITIES

The Double Slit Experiment – Wave-particle differences – The Wave-Particle Dual Behavior – Einstein Was Confused, Not Quantum Theory – Nobody Understands Quantum Mechanics – Nature Is Absurd – Is It Possible That Nature Is So Absurd? – Quantum Superposition and Schrödinger's Cat – Interpretation of Copenhagen Quantum Theory – The Quantum Leap or Entanglement – Bohr and His Revolutionary Atomic Model – Bilocation – Quantum Computing – EPR Experiment and Spooky Action at a Distance – Aspect and Entanglement – Grinberg and Nonlocality in Brains – Wheeler's Ray – Bell's Test – BIG Bell Test – Connection Between Emotions and DNA – Cleve Backster and His Experiments – Poponin and Biology Quantum Entangling – Invisible Clinics – Glein and the Affectation of Biological Systems – Experiences in Universities Testing Quantum Entanglement – The Chinese and Teleportation or Quantum Transportation – China, a Pioneer in Quantum Technology in Space – Connections in the Non-Local Domains of Consciousness – The Cosmos as a Network – Fields of Physical and Mental Interaction – Global Quantum Internet, Quantum Cryptography – The Uncertainty Principle – Pollak and the tunnel effect – Nature doesn't care if we understand it or not – Microcosm and macrocosm are radically different in their behavior – Chaos theory and the butterfly effect.

In the subatomic world, nature has a different behavior from the macroscopic world, strict causality (every cause does have its corresponding effect) and certainty do not operate, however strange all this may appear.

Let's take a brief look at four of the most significant quantum oddities: the double-slit experiment, Schrödinger's cat, quantum leap, and the uncertainty principle.

The reader should not expect to understand them, for even the most accomplished quantum physicists have no satisfactory explanations for them, but they are experimentally demonstrated. If you are not patient and curious about these matters, if they make you dizzy, you may well move on to the next chapter or skip the paragraphs that make you uncomfortable. There are technicalities within quantum physics that generate vertigo and states of idiocy for those of us who are neither familiar nor properly interested.

For those who are more restless with this branch of science, there is a range of multiple areas in which to delve and deepen. Wave functions, probabilities, incessant energetic fluctuations of the vacuum, quantum chromodynamics, quantum cryptography, mutual dependence of space and time, the relative character of simultaneity, the warping of the structure of space-time, black and worm holes, big bang, energies capable of pulverizing matter into fragments as small as a trillionth of a meter,  electroweak quantum theory, standard model of particle physics, complementarity experiments, delayed action experiments, psychokinesis, quantum teleportation or transmission of quantum state information between entangled particles, matter and antimatter, the principle of superposition and its collapse studying the boundary between biology and quantum physics investigated by the PAPETS project of the European Union,  quantum tunneling, cosmic microwave background radiation, inflationary models, electroweak theory, John Wheeler's experiments with the photon and type of observation, chaos theory, Noether's theorem, Hamilton's principle of action, Roger Penrose's theory of twistors, Schrödinger's equation,  Space Hilbert's transformations, Lorentz transformations, density matrices, WEYL's curvature, Hawking's box, Dirac's equation, Landau's ghost, Euler's beta function, the De Broglie-Bohm model, physicist Hugh Everett's theory of parallel universes, supergravity and its derivation in supersymmetries (described as the square root of space-time,  with no less than 60 particles) a long etcetera. Of course we're not going to go into any of this in this paper.

Next edition: The double-slit experiment (Part 2)