Relativity Science Calculator - Some Consequences of E=mc2


1). Laws of Conservation of Relativistic Momentum and Energy:


1a). Example of Relativistic ( or Effective ) Momentum:

Let rest mass in  , achieve a relative velocity of , say 0.88, to a stationary observer in  .

Therefore, the relativistic or effective mass calculated by our stationary observer in    is given by

And, relativistic momentum in terms of "classical momentum" of    is simply derived as follows:

note : this example is used in the future upcoming Relativity Calculator Mac application

2). invariance_E2.png:

Because of different relative velocities for different observers in different frames of reference, the values of and ( momentum and energy respectively ) will accordingly be different for different observers residing in different systems. 



will always have the same value for all observers in all moving frames of reference. This essentially states that the magnitude of the energy - momentum vector is equal to the mass rest energy, where in particle physics rest mass, also known as proper mass,


is invariant for all observers in all frames of reference.

Here's a simple heuristic for this vital relationship:


Another important energy - momentum relationship is given by


and appears in nature for a quanta of light energy where    as follows: 


2a). Derivation of momentum energy velocity:


2b). Derivation of heading2.png:


Also please notice that the rest mass of a quanta of light energy is always zero since there is no reference frame in which the light photon is at rest and hence the following is further confirmation of nature's reality:

momentum equals energy divided by c.

This last equation expresses the relationship between the momentum of a quanta light photon and the energy of a flash of light. This relationship was also used by Einstein in his proof of the fundamental law of the inertia of energy.

2c). Much Simpler Derivation of heading2.png:

2d). Example for heading2.png:∗∗

The classical electron radius is

According to T. Jacobson, Department of Physics, University of Oslo, whose paper,   "An empirical mass formula for and leptons and some remarks on trident production", February 2, 2008, suggests the electron may itself possess an inner constituent structure, therefore for the sake of argument let's say that some unknown constituent of the electron has rest mass of

Using Heisenberg's Uncertainty Principle, the unknown constituent must reside somewhere within the classical electron radius and hence

∗∗note : this example is used in the future upcoming Relativity Calculator Mac application

2e). Now we'll prove the  invariance_E22.png:

i). Let   have relative velocity as it moves away from system  .  Also assume that a mass - particle has velocity    in  . Then by the addition of relativistic velocities  we also know that 

mass-particle velocity

will be the velocity of a mass - particle for an observer in  .

Finally, assume the following: 

momentum energy schema.

Here we go:

Let   = 1, unity, where velocities  ,    are simply some fraction of    in both    and   systems. [ note: we make    as a unity in order to simplify our equations and will bring it back at  the end of our mathematical endeavors as will be shortly seen. ] Hence the following is also true: 

simplified addition of velocities

momentum derivation.

ii). Continuing ... 

Energy derivation

iii). We can thus see that

analogous Lorentz transformations.png.

Hence the Lorentz transformations for these energies and momenta for a mass - particle moving with velocity    in   as they are viewed in    are indeed invariant!

iv). A corollary: assuming that   is moving not strictly parallel to the x - axis of  ,  then we have these vector components respectively


End of proof.

2f). The significance of  invariance_E22.png:

straight - line of sight Dopplerstraight - line of sight Doppler

But more importantly, the invariance of the "energy - momentum" vector determines the fact that rest mass is always a constant notwithstanding that in each respective moving reference frame, differing amounts of relativistic mass will be observed and hence measured!

Common sense, of course, dictates that whenever you as the observer are stationary relative to a body of mass that that mass will not only be at rest but also that the "amount" of rest mass remains constant ! It is only when a body of mass begins to move at a significant fraction of the speed of light relative to you as the observer, that the body of mass begins to "grow" in quantity!! Still, relativity mathematics confirms any person's common sense understanding that rest ( or proper ) mass is always a constant.

Finally, the invariance of the "energy - momentum" vector simply expresses the conservation of total energy precisely because it is invariant under Lorentz transformation!

3). Computing or :

computing p.e.

If we know either  or of a mass - particle or a quanta of energy, the obverse is easily derived.

For example, a flash of light is pure kinetic energy with rest mass   = 0  ( since it is meaningless to speak of a frame of reference where light photons or "light quanta" are ever at rest )  and velocity  .



which is what Einstein used in his proof of the fundamental law of the inertia of light energy !

4). light as a "packet" or quanta of energy :

Because light is composed of pure kinetic energy with velocity    always in all frames of reference, and 


this formulation breaks down completely and is in fact irrelevant for light energy as follows: 

rest mass meaningless.png.

On the other hand we do have the following quantum or wave relationship between light energy and frequency: 

quantum definition.png

But nevertheless from before

light as wave.png.

4a). Proof of photon mass = 0:

Analogous to Newton's Law of Universal Gravitational Force Attraction, we also have Coulomb's Law of Force Attraction between charged electrical particles:

For any photon, therefore, to be at rest, it will have to exist at an infinite distance in space - time from any other [ arbitrary ] photon in space - time in order that

By applying Heisenberg's Uncertainty Principle

4b). If the photon rest mass = 0, how come light is bent in a gravity field?:

Newton's Theory of Gravity requires that there be two masses at a given distance ( Einstein: spooky 'action at a distance' ) from each other for a force of attraction to exist between them:

The answer lies in Einstein's General Theory of Relativity which differs from Newton's concept of space and time as follows:

In other words, it is not that one body of mass directly attracts another body of mass, but rather that bodies of mass deform the fabric of spacetime and therefore bodies of mass follow a path of least energy expenditure according to both the mathematics of Hamilton's Principle and Einstein's General Relativity mathematics which Einstein interestingly and recursively derived from William Rowan Hamilton ( 1805 - 1865 )'s Principle! See: "Hamilton's Principle And The General Theory of Relativity", by A. Einstein, translated from "Hamiltonsches Princip und allgemeine Relativitätstheorie", found in "The Principle of Relativity", Dover Publications, Inc.

Therefore, The bending of light as it passes close by a gravity field induced by a body of mass is not that there's a direct Newtonian mutual force of attraction between massless photons and a body of mass such as the sun, but rather that a beam of light follows a path of least energy expenditure as laid down by the fabric of spacetime prescribed by the nearby body of mass!

It was Sir Arthur Eddington ( 1882 - 1944 ) who famously travelled to Portuguese-speaking Isle Principe, an island in the Gulf of Guinea off the west coast of Africa, on May 29, 1919 during a total solar eclipse, to tentatively confirm Einstein's 1915 General Theory of Relativity:

source: Google maps

The final and strongest confirmation of General Relativity mathematics for the bending of starlight across the sun's corona came during a solar eclipse in Australia when American astronomer William Wallace Campbell ( 1862 - 1938, Director Lick Observatory from 1901 to 1930 ) in 1922 provided the final and most definitive empirical confirmation for Einstein's general relativity mathematics.

See:    "On the influence of Gravitation on the Propagation of Light" ( "Über den Einfluß der Schwerkraft auf die Ausbreitung des Lichtes" ), by Albert Einstein, Annalen der Physik 35(10): 898 - 908, 1911, in the original German.

Also:    "On the influence of Gravitation on the Propagation of Light", by Albert Einstein, Annalen der Physik 35(10): 898 - 908, 1911, English version, translator Michael D. Godfrey, Information Systems Lab, Stanford University

5). Example of light as a "packet" or quanta of energy from Israeli - Weapons YouTube site:

Click here for US and Israel Weapons systems development: MTHEL ( Mobile Tactical High Energy Laser ) movie

We are therefore left with the following conclusions regarding light: 

▶ The explanation of light as a mass - particle or photon, where rest mass   = 0, is not an entirely satisfactory concept nor even as a fully comprehensive explanation; rather light is  somewhat more akin to a probabilistic wave function where exact location and momentum for the "light quanta" are inherently and simultaneously "uncertain"

The better equations for a "packet" or quanta of light energy  thus becomes

better light equations.png.

▶ Corollaries to all of this:

(i). If so - called light mass - particles or photons exhibit probabilistic wave function characteristics, then why not other mass - particles? Sub - atomic particles for instance?? In other words, all matter and not just light possesses a wave-particle duality  which is precisely the de Broglie Hypothesis of Louis de Broglie for which he was awarded the 1929 Nobel Prize for Physics.

(ii). Heisenberg Uncertainty Principle - Werner Heisenberg was a celebrated German physicist who received the Nobel Prize in Physics in 1932 for Quantum Mechanics ( he also was a loyal Nazi in Hitler's Germany who was working on Hitler's "secret projects" [ or was he slowling them down according to some historians? ] as well as [ perhaps? this part is not so certain ] on the "Final Solution" to the "Jewish Question" and the "American Question" ), nevertheless his major contribution to atomic physics can be somewhat easily  described as follows:

probability densities.png

Dirac's Constant.png

6). Summary: