Oscillating Particles

Oscillating Photon - 004

Is it possible that photons of light are oscillating particles which when observed collectively can exhibit patterns of wavelike interference?…

Consider the possibility that maybe we live in a “discrete space-time” universe and that Quantum Mechanics is merely a physical manifestations of the “discretization” of Euler’s Formula; and all photons are in fact “oscillating particles”.

If so oscillating particles would, collectively, exhibit on observation wave-interference-like behaviour, which would neatly explain the experimental observations of double-slit experiment; and in doing so, allow us to assign the concept of “wave-particle duality” (and all the “weirdness” that goes with it) to the dustbin of history…


Euler’s Formula

Euler’s Formula ( eix = cos(x) + i sin(x) where x is an angle measured in radians) is a mathematical tool used to describe how a “vector rotates” through an angle in the complex plane, but it can also be used to describe a “periodic oscillation”.

The equation for an oscillation can be written as Ae(iωt) where (A) is the amplitude of oscillation, and (e(iωt) ) is the changing phase of oscillation over time.  In this phase term, the angle (x) in Euler’s Formula has been replaced with angular-frequency (ω) multiplied by time (t) in order to allow for the position of the oscillating body to change over time.

Angular frequency is usually expressed in radians per second and is normally assumed to be “continuous change over continuous time”.  But what if, in reality, “Time” is NOT “continuous”, but actually occurs in tiny “discrete incremental steps”; what if there is actually some “smallest fundamental unit of time”?


Fundamental Units

Let’s take a guess that the fundamental unit of time might have the same magnitude as the value of Planck’s Constant.

(1 h-second  =  6.626  ×  10-34 seconds)

Furthermore let’s define a “unit of angular displacement” using Euler’s Formula.  Let’s define this unit to have the same magnitude as the value of Planck’s Reduced Constant.

(1 h-cycle  =  6.626  x  10-34 cycles)

(1 (h/2π)-cycle  =  1 ħ-cycle  =  1.054571726  x  10-34 cycles)

(1 ħ-radian = 1.054571726  x  10-34 radians)

euler -4

eix   =   cos(x) +  i sin(x)

ei   =   cos(1) +  i sin(1)

eiħ   =   cos(ħ) +  i sin(ħ)

eiħ   =   (0.999999 +  iħ)

Given this defined ħ-unit of angular displacement”, we can now think of every other size of angular displacement as an integer number of units of (1 +iħ);

 (eiħ)n   =   (ei)ħn   =   einħ   =   (1 + iħ)n   =   n ħ-radians   (where n = 1,2,3….)

And when n = Ħ =  9.48252238653324  ×  10+33 (i.e. capital-h-bar : the inverse of  ħ) we get an angle of

  (eiħ)Ħ   =   (ei)ħĦ   =   ei   =   (1 + iħ)Ħ   =   Ħ ħ-radians =   1 radian



Let us now look at a possible physical realization of this discrete mathematics.  Let’s look at an up and down oscillation (on the y axis) that occurs in discrete incremental steps of size (n ħ-radians).

Initial Displacement:  y = A sin(nħ)                        (equation 1)

In order to evolve this initial displacement over incremental time, we will replace (nħ) with (ωt) — where (ω = nħ/t ) and where time (t) is measured in h-seconds, and can only have integer values (i.e. t = 1,2,3… h-seconds.)

       Displacement over Time:  y = A sin(ωt)                              (equation 2)

Associated with this oscillation is an incremental velocity

v  =  Aω cos(ωt)                                                 (equation 3)

The momentum associated with this velocity is given by

p = mAω cos(ωt)                                             (equation 4)

If we multiply this momentum by velocity we get

pv = mA2ω2 cos2(ωt)                                         (equation 5)

We can rewrite equation (5) in angular form replacing (mA2) with the moment of inertia (I)

pv = Iω2 cos2(ωt)                                              (equation 6)

And since (Iω) represents angular momentum, we could guess that maybe it actually represents a single discrete ħ-unit of angular momentum which is represented by (ħ).

pv = ħω cos2(ωt)                                              (equation 7)

Equation (7) is effectively an equation for the kinetic energy of an oscillating particle, which means there must be a potential energy associated with it, and consequently the total energy of the oscillation (at any given moment in time) is distributed between kinetic and potential energy and expressed as a function of time

 E(t) =  ħω(cos2(ωt) + sin2(ωt))                      (equation 8)

Lastly to obtain a travelling, or moving, version of this oscillation equation we use the relationship between angular frequency and the linear velocity of the particle (i.e. ω=kv where k is the so-called wave number and v is the linear velocity of the particle) and so equation (8) can now be expressed as a function of both time and distance

E(x,t) = ħω(cos2(kvt) + sin2(kvt))                (equation 9)

Planck-Einstein Relation

The Planck-Einstein Relation (E=hf) tells us that energy is proportional to frequency.  The discretization of Euler’s Formula suggest that different frequencies represent, different amounts of “oscillation units” in a particle.  It suggests that (h) is a unit of angular momentum, that (f) is the number of these units in a single h-second, which makes (E) equal to an amount of angular momentum per unit time.

Equation (9) is an extended version of the Planck-Einstein Relation that incorporates an oscillation within a moving particle.  This equation bears some resemblance to the Schrodinger Wave Equation which has a wave function of the form Aei(kx+ωt) incorporated into a conservation of energy equation.  Equation (9) however is both an oscillation function and a conservation of energy equation, where phase-over-distance and phase-over-time are combined in a single term Aei(kvt).  This is an equation for a travelling “oscillating particle” not a “probability wave”…


No Medium Required

In the classical world “waves” travel through a medium, because classical waves involve the transport of energy without the transport of matter.  In a water wave for instance, particles oscillate in situ while the wave moves from one particle to the next.  In the quantum world however maybe particles oscillate as they move –- if so, no medium is required.

Phase Information

An oscillating particle would carry with it its own “phase-information”.  This means that a particle always knows where it is in its own cycle, and therefore how much of its total energy is being expressed as kinetic energy at any moment in time.  Interaction with multiple particles at different points in their individual cycles would consequently yield wave-interference-like results because the particles would, on interaction, either be absorbed or not absorbed depending on where they are in their own individual cycle.

Phase-Size + Number-of-Phases

In a discrete oscillation angular frequency describes the size of a “discrete phase-step” over time.  We know that the size of the phase-step (nħ) is effectively the step-size of oscillation.  We also know that the step-size times the number-of-steps in a cycle is always a constant 2π radians.  This means that, in a discrete oscillation, as the amount of change that occurs in one unit of time goes up , the number of steps must comes down.

Wave-like vs. Particle-like

The number of phases determines the degree of wave-like behaviour.  Smaller phase-size means more phases per cycle; and consequently more wave-like the behaviour.  But as the frequency/phase-size goes up the number-of-phases comes down, and so the behaviour would become less wave-like, more particle-like…


1. Double Slit Experiment

Noble Laureate Richard Feynman once famously said that the only real mystery in Quantum Theory is the Double-Slit Experiment.  This experiment suggests “Wave-Particle Duality” of both light and matter, and seems to support the concept of particle “Superposition” (not only in space but also in time).

Currently quantum physics effectively ignores what a quantum particle is actually doing (during its travel from source to receiver) and only talks about the mathematics of the “wave-function” associated with the particle.  In the double-slit experiment it is thought that it is not the particle itself but the particle’s wave-function that goes through both slits at the same time.

If however all particles have their own oscillation-function, then any particle going through one slit will carry with it phase information which will determine the amount of kinetic energy that is transferred on contact with the screen; and so over time (as long as there is no decoherence at source) many oscillating particle will cause interference-like patterns to emerge…

Thus individual particle phase information can explain the double-slit experiment without the need for the concept of “Wave-Particle Duality”.  With multiple particles (emitted from the same coherence source), there is no need for the “Superposition Principle”; nor is there any need for “an observer” to cause the so-called “collapse” of wave-function (i.e. no need for the so-called “Copenhagen Interpretation”).

2. The Schrodinger Wave Equation

The Schrodinger Wave Equation (SWE) is a wave equation for “matter waves” and a bedrock of Quantum Theory, but if Quantum Mechanics is really all about oscillating particles rather than probability waves, then how can this wave-equation produce such phenomenally accurate results?

For three reasons.  The SWE is an excellent fit with the concept of an oscillating particle because firstly its wave function contains both the phase-over-time (angular frequency) and phase-over-distance (wave-number), secondly this function is incorporated inside a conservation of energy equation, and lastly but most importantly this formulation only truly works because of “The Law of Large Numbers (LLN)”.

The SWE basically describes the probabilistic AGGREGATE behaviour of multiple oscillating particles; but it relies on the LLN to convert this “probabilistic behaviour” into “accurate predictions”.   This means that the SWE  does not work in the singular, it only works in the collective (thus leading to the need for the superposition principle); but with quantum mechanical systems (as with thermal systems), understanding collective behaviour of billions of tiny particles (or the average behaviour over time of a single particle) is usually all that we need (unless we are trying to figure out how a single particle can be in multiple places at the same time!…).  

3. Spin

A particle “oscillating” does so back and forth in opposite directions. We can think of one direction as being from positive to negative (through +i on the complex plane), and the other as negative to positive (through –i on the complex plane).  Thus any two particles with a phase difference of exactly 180 degrees will always be moving in opposite directions.

4. Entanglement

The Bell inequality experiments are considered to be the final death-nail to Einstein’s misgivings about the “Copenhagen Interpretation” and its consequential weirdness for quantum mechanics.

The results of these experiments would seem to prove that that entangled quantum particles are more correlated than they should be according to classical mechanics (i.e. experiments show that particles with different phase-angles-of-polarization express higher correlation than is possible in classical mechanics).

However the Bell inequality test assumes that the particles are moving like bullets in a straight-line linear fashion.  But if particles are indeed oscillating as they move, then the amount of correlation that we witness in experiments turns out to be exactly in line with expectations (when we take both the phase-angle-of-polarization and the phase-of-oscillation into account).  Hence since there is no unexplainable excessive correlation, there is no need for any so-called “spooky-action-at-a-distance”.

5. Tunnelling

The discovery of E=hf  might possibly have been first real piece of evidence that the universe is in fact an entirely discrete system; and that even those things that appear continuous are in reality discrete at the tiniest scales.  This would mean that there is no such thing as pure continuous movement; all movements are discrete and can be jumpy at high frequency which can lead to the possibility of so-called “Quantum Tunnelling”.

6. String Theory

Another interesting thing about a “incremental step-size of oscillation”, is that most higher frequency “coarse oscillations” do not produce regular, tick-tock-like symmetrical behaviour about equilibrium.  On the contrary, most high energy coarse oscillations appear to produce asymmetrical behaviour about equilibrium causing matter-like structures to emerge.  Furthermore this Coarse Harmonic Motionand the resultant emergent dissymmetry suggests support for some of the ideas behind String Theory (except that it supports oscillating particles, not oscillating strings).

7. Quantum Theory + General Relativity

The primary conflict between Quantum Theory and General Relativity is that General Relativity understands empty space as being exactly that, smooth flat empty space; but the “Uncertainty Principle” of Quantum Mechanics disagrees, because according to it, at the tiniest scales of empty space so-called “Quantum Fluctuations” must emerge.

However with the demise of the Superposition Principle, we would have no further need for the Uncertainty Principle; which means we can zoom in on smaller and smaller scales of empty space (space-time) without worrying about the emergence of this dreaded “Quantum Foam”.

Without quantum fluctuations there is no longer any conflict between Quantum Mechanics and General Relativity.  In a discrete universe, Quantum Mechanics and General Relativity are simply the two extremes of, what we could think of, the curvature/warping of space-time…

[Postscript: If you think all of this is heresy, and flies in the face of the well established consensus understanding of modern day physics, then take a look at this https://youtu.be/ZacggH9wB7Y]