Nikola Tesla's Legacy

'Ere many generations pass, our machinery will be driven by a power obtainable at any point of the universe. Throughout space there is energy. — Nikola Tesla, 1892

Nikola Tesla c. 1879 at age 23

Serbian-American Nikola Tesla (Никола Тесла; 10 July 1856 – 7 January 1943) was an inventor, physicist, mechanical engineer, electrical engineer, futurist and a great loss for mankind.

A man who was born a century or more ahead of his time, . . . with an unfathomable thinking of what is to come, gifted mankind so much including his famous lost works.

Tesla (9th from left), along with some of the greatest scientists at that time, including Albert Einstein (8th from left), taking an inspection tour of the New Brunswick Marconi Station. Circa 1921

With a scale of highest probability, some of his works have been perfected but kept out of the mindset of governments and capitalists more engrossed in … you probably know what this means and some have been deliberately withheld for self serving or other rightful intentions.

The Missing Secrets Of Nikola Tesla

 

From Google Videos
Uploaded by SowhatNC on Oct 29, 2009

Some of his lost secrets are as follows:

Mechanical Oscillator: compresses air until the air is a liquid

Anti-Gravity Aircraft: electric aircraft

Free Energy: Renewable electricity and heat tapped from the natural energy sources

Earthquake Machine: a pocket-sized device that could shake a house apart with building waves of energy.

Force Field: a Scalar field dome made of energy that will eventually be built big enough to protect a city from attack during wars

Death ray: destructive energy transmitter he claimed to have built - "when unavoidable... may be used to destroy property and life." --- Tesla, 1915.

Thought Camera: In 1933, Tesla theorized about a device that could photograph thoughts.

"I expect to photograph thoughts... In 1893, while engaged in certain investigations, I became convinced that a definite image formed in thought, must by reflex action, produce a corresponding image on the retina, which might be read by a suitable apparatus. This brought me to my system of television which I announced at that time... 

 

Wireless transmission of power and energy 

demonstration during his high frequency and potential lecture of 1891

 In 1898, Tesla demonstrated a radio-controlled boat (U.S. Patent 613,809 — Method of an Apparatus for Controlling Mechanism of Moving Vehicle or Vehicles).

 An experiment in Colorado Springs. This bank of lights is receiving power by means of electrodynamic induction from a nearby transmitter

Tesla's Wardenclyffe plant on Long Island in partial stage of completion. Work on the 55-foot-diameter (17 m) cupola had not yet begun. There is a coal car parked next to the building. From this facility, Tesla hoped to demonstrate wireless transmission of electrical energy across the Atlantic. Circa 1902. 

Nikola Tesla, with Ruđer Bošković's book Theoria Philosophiae Naturalis, sits in front of the spiral coil of his high-frequency transformer at East Houston Street, New York.

Publicity picture of Nikola Tesla sitting in his laboratory in Colorado Springs with his "Magnifying transmitter" generating millions of volts. The arcs are about 7 meters (23 ft) long. (Tesla's notes identify this as a multiple exposure photograph.)

Nikola Tesla's prediction for the
future of the human race

 

Uploaded by nickharvey7 on Jan 5, 2011

Nikola Tesla said that "The day when we shall know exactly what electricity is will chronicle an event probably greater more important, than any other recorded in the history of the human race"

This video explains a theory that the positive and negative of electric charge is linked to the reason why we have a future and a past forming an Arrow of Time. If this theory is correct then Nikola Tesla prediction was right.

If our eyes worked at a different wavelength we would be able to see that electric charge is an innate property of matter. We would see that everything is radiating light wave of electromagnetic radiation continuously. Objects interact with the particle wave duality of light continuously forming new electromagnetic waves.

In a new theory this universal and continuous process forms the time continuum or Arrow of time itself. Therefore the uncertainty and probability of everyday life is the same uncertainty we have in quantum physics.

The atoms bound together and then collapse the particle wave duality of light in unison forming the uncertainty of their own potential future position and momentum relative to their energy or mass. We see and feel this as the forward passage of time.

We have an Arrow of time, but we also have Proper Time. The rate that time flows relative to the energy or mass of an object. Time will run slower around an object of great mass forming time dilation and the geometry of Einstein's curvature of spacetime.

We all form our own future spacetime relative to our energy or mass that will have a potential probability of our future position and momentum.

Therefore Heisenberg's Uncertainty Principle of quantum physics is the same uncertainty that we have in our everyday life.

   

Sources: Wikipedia.
http://en.wikipedia.org/wiki/Nikola Tesla ,
Wikimedia Commons, Youtube

http://fromd.blogspot.com 

email: voicefromdorient@yahoo.com

A Brief History Of Quantum Mechanics

The history of quantum mechanics began essentially with the 1838 discovery of cathode rays by Michael Faraday, the 1859 statement of the black body radiation problem by Gustav Kirchhoff, the 1877 suggestion by Ludwig Boltzmann that the energy states of a physical system could be discrete, and the 1900 quantum hypothesis by Max Planck that any energy is radiated and absorbed in quantities divisible by discrete energy elements, E, such that each of these energy elements is proportional to the frequency ν with which they each individually radiate energy.

Planck insisted that this was simply an aspect of the processes of absorption and emission of radiation and had nothing to do with the physical reality of the radiation itself.

However, at that time, this appeared not to explain the photoelectric effect (1839), i.e. that shining light on certain materials can function to eject electrons from the material.

Solvay conference 1927

This file is in the public domain, because the image, photographed by Benjamin Couprie, owned by the Institut International de Physique Solvay, 

was published in Brussels, Belgium more than 70 years ago.

From back to front and from left to right :

Auguste Piccard, Émile Henriot, Paul Ehrenfest, Édouard Herzen, Théophile de Donder, Erwin Schrödinger, Jules-Émile Verschaffelt, Wolfgang Pauli, Werner Heisenberg, Ralph Howard Fowler, Léon Brillouin, Peter Debye, Martin Knudsen, William Lawrence Bragg, Hendrik Anthony Kramers, Paul Dirac, Arthur Compton, Louis de Broglie, Max Born, Niels Bohr, Irving Langmuir, Max Planck, Marie Skłodowska Curie, Hendrik Lorentz, Albert Einstein, Paul Langevin, Charles Eugène Guye, Charles Thomson Rees Wilson, Owen Willans Richardson

In 1905, basing his work on Plancks quantum hypothesis, Albert Einstein postulated that light itself consists of individual quanta. These later came to be called photons (1926). From Einstein's simple postulation was born a flurry of debating, theorizing and testing, and thus, the entire field of quantum physics.

 
Quantum mechanics (QM) is a set of principles describing the physical reality at the atomic level of matter (molecules and atoms) and the subatomic (electrons, protons, and even smaller particles). These descriptions include the simultaneous wave-like and particle-like behavior of both matter and radiation ("waveparticle duality").

Quantum Mechanics is a mathematical description of reality, like any scientific model. Some of its predictions and implications go against the "common sense" of how humans see a set of bodies (a system) behave. This isn't necessarily a failure of Quantum mechanics - it's more of a reflection of how humans understand space and time on larger scales (e.g., centimetres, seconds) rather than much smaller.

A Brief History Of Quantum Mechanics



Uploaded by Best0fScience on Dec 24, 2009

Quantum mechanics says that the most complete description of a system is its wavefunction, which is just a number varying between time and place. One can derive things from the wavefunction, such as the position of a particle, or its momentum. Yet the wavefunction describes probabilities, and some physical quantities which classical physics would assume are both fully defined together simultaneously for a system are not simultaneously given definite values in Quantum mechanics.
 
It is not that the experimental equipment is not precise enough - the two quantities in question just are not defined at the same time by the Universe. For instance, location and velocity do not exist simultaneously for a body (this is called the Heisenberg uncertainty principle)

Certain systems, however, do exhibit quantum mechanical effects on a larger scale; superfluidity (the frictionless flow of a liquid at temperatures near absolute zero) is one well-known example. Quantum theory also provides accurate descriptions for many previously unexplained phenomena such as black body radiation and the stability of electron orbitals. It has also given insight into the workings of many different biological systems, including smell receptors and protein structures.
 
Even so, classical physics often can be a good approximation to results otherwise obtained by quantum physics, typically in circumstances with large numbers of particles or large quantum numbers. (However, some open questions remain in the field of quantum chaos.) 

It just needs to take some more geniuses to connect both the most recent affirmation of the God's particle existence and probable relations with quantum mechanics and see if there can be more usefulness in applicable technology.

Sources: 

Wikipedia, Wikimedia Commons, Best0fScience

http://www.facebook.com/ScienceReason ... 

Quantum Mechanics (Chapter 1): A Brief History Of Quantum Mechanics.
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1. A Brief History Of Quantum Mechanics
http://www.youtube.com/watch?v=B7pACq_xWyw
2. The Structure Of Atoms
http://www.youtube.com/watch?v=-YYBCNQnYNM
3. Wave Function And Wave-Particle Duality
http://www.youtube.com/watch?v=7GTCus7KTb0
4. The Uncertainty Principle
http://www.youtube.com/watch?v=Fw6dI7cguCg
5. The Spin Of Fundamental Particles
6. Quantum Entanglement 

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