Some might disagree by pointing out that we cannot know the full extent of our universe because the speed of light puts limits on our ability to observe parts beyond a specific point.  However some could also argue that anything beyond that point is not in our observable universe and because of that it cannot be a part of it.

Yet even though Einstein’s theories does not mathematical rule out the possibility of an infinite universe it does not predict that one exists.

However the same cannot be said of Quantum Mechanics which mathematical defines mass, energy and forces in terms of a one dimensional point.  Infinities arise because the forces and energies associated with the integrals which define them become larger as they approach each other reaching infinity when they come in contact.

The difference between these quantum mechanical infinites and relativistic ones is that they occur with the limits of our observable universe.  In other words it predicts existence of masses, forces, and energies that are infinite within its finite boundaries.

Some might think this indicates the basic concepts of quantum mechanics that define our in terms of the mathematical properties of a one dimensional point is incorrect because most physicists and mathematicians would agree that the infinite entity cannot exist in a finite environment.

However its proponents disagree and have devised a clever method called renormalization which alters the mathematical relationships between the parameters in the theory to make these infinites disappear.

Granted even though one may be able to use renormalization to alter the mathematical relationships between point particles to eliminate infinites they cannot change the fact the point particle responsible for those infinities still exists before those alterations take place.  In other words it assumes they exist before renormalization takes place because if they did not there would be no need for renormalization.  Therefore even though the process of renormalization solves the mathematical problem of infinities it does nothing to solve the conceptual one that exist within the framework of quantum mechanics because it relies on the existence of point particles which as mentioned earlier are responsible for the infinites. `

Why then are we still using it to explain or predict that reality?

The most probable answer is because it predicts with amazing precision the results of every experiment involving the quantum world that has ever been devised to test it: so much so that many are willing to overlook the obvious fact that as was just mentioned the conceptual arguments use to make those predictions have a fatal flaw.

However we are not going to concern ourselves with resurrecting the conceptual content of quantum mechanics as has been the focus of the past three quarters of a century but instead will define another theory that can explain the behavior of energy/mass in terms of the properties of our observable environment in a way that eliminates the need for any “adhco” procedures such as renormalization to make it consistent with that behavior.

To do this one must be able to, in a logical and consistent manner using only the physical laws of our observable environment explain the existence of the four basic components of a quantum world: the fact that energy/mass is quantized, Planck’s constant, Heisenbergâ€s Uncertainty Principle and the reason one can use probabilities to define a particles position.

For example in the article “Why is energy/mass quantized?” Oct. 4, 2007 it was shown it is possible to explain and predict the quantum mechanical properties of energy/mass associated with Schrödinger’s wave function by extrapolating the laws of classical resonance in a three-dimensional environment to a matter wave on a “surface” of a three-dimensional space manifold with respect to a fourth *spatial* dimension.

(Note: Einstein has already gave us a detailed mathematical description of this environment when he used the constant velocity of light to define the geometric properties of space-time because it allows one to convert a unit of time in his four dimensional space-time universe to a unit of space in a one consisting of only four *spatial* dimensions.   Additionally because the velocity of light is constant it is possible to mathematically derive a one to one correspondence between his space-time universe and one made up of only four *spatial* dimensions.)

Briefly it showed the four conditions required for resonance to occur in a classical environment, an object, or substance with a natural frequency, a forcing function at the same frequency as the natural frequency, the lack of a damping frequency and the ability for the substance to oscillate spatial would be meet by a matter wave in an environment of four *spatial* dimensions.

(Louis de Broglie was the first to theorize that all particles are made up of matter waves.  His theories were later confirmed by the discovery of electron diffraction by crystals in 1927 by Davisson and Germer.)

The existence of four *spatial* dimensions would give a matter wave the ability to oscillate spatially on a “surface” between a third and fourth *spatial* dimensions thereby fulfilling one of the requirements for classical resonance to occur.

These oscillations would be caused by an event such as the decay of a subatomic particle or the shifting of an electron in an atomic orbital.  This would force the “surface” of a three-dimensional space manifold with respect to a fourth *spatial* dimension to oscillate with the frequency associated with the energy of that event.

The oscillations caused by such an event would serve as forcing function allowing a resonant system or “structure” to be established in four *spatial* dimensions.

Classical mechanics tells us the energy of a resonant system can only take on the discrete or quantized values associated with its resonant or a harmonic of its resonant frequency.

Additionally it also tells us why in terms of the physical properties four dimensional space-time or four *spatial* dimensions an electron cannot fall into the nucleus is because, as was shown in that article all energy is contained in four dimensional resonant systems. In other words the energy released by an electron “falling” into it would have to manifest itself in terms of a resonate system. Since the fundamental or lowest frequency available for a stable resonate system in either four dimensional space-time or four spatial dimension corresponds to the energy of an electron it becomes one of the fundamental energy unit of the universe.

This shows how one can conceptually derive the quantum mechanical properties energy/mass in terms of wave properties of particles observed by Davisson and Germer by assuming that they are a result of resonant properties of four *spatial* dimensions.

In other words if one assumes as is done here that its mathematical properties of Schrödinger’s wave function are representative of wave moving on a “surface” of a three-dimensional space manifold with respect to a fourth *spatial* dimension one can form a physical image of why energy/mass is quantized in terms of the properties of our observable environment.

However it also gives one the ability to define the physical boundaries of a particle and its energy in terms of the observable properties of our environment

In classical physics, a point on the two-dimensional surface of paper is confined to that surface.  However, that surface can oscillate up or down with respect to three-dimensional space. 

Similarly an object occupying a volume of three-dimensional space would be confined to it however, it could, similar to the surface of the paper oscillate “up” or “down” with respect to a fourth *spatial* dimension.

The confinement of the “upward” and “downward” oscillations of a three-dimension volume with respect to a fourth *spatial* dimension is what defines the geometric boundaries or the “box” containing the wave component of Schrödinger’s wave function the article “Why is energy/mass quantized?” Oct. 4, 2007 associated with a particle. 

As mentioned earlier infinites arise in Quantum Mechanics when one applies the concept of mathematical one dimensional point to define mass, energy and forces results their integrals to become increasing larger as they approach each other reaching infinity when they come in contact. 

However the above theoretical concepts provides a solution because it shows that a particle’s energy is not confined to a one dimension point but instead exists in an extended spatial volume associated with its resonant structure.

Yet if true one must be able derive the physical meaning the other fundamental concepts of quantum mechanics like Planck’s constant or 6.626068 × 10^-34 (kg*m2/s), Heisenbergâ€s Uncertainty Principle and the probabilities associated with Schrödinger’s wave function by extrapolating the laws of classical physics in a three-dimensional environment to a fourth *spatial* dimension.

Planck’s constant is one of fundamental components of Quantum Physics and along with Heisenbergâ€s Uncertainty Principle it defines the uncertainty in the ability to measure more than one quantum variable at a time.  For example attempting to measure an elementary particleâ€s position (â–²x) to the highest degree of accuracy leads to an increasing uncertainty in being able to measure the particleâ€s momentum (â–²p) to an equally high degree of accuracy.  Heisenbergâ€s Principle is typically written mathematically as â–²xâ–²p  Â³ h / 2  where h represents Planck constant

As mentioned earlier the resonant wave that corresponds to the quantum mechanical wave function defined in the article “Why is energy/mass quantized?” Oct. 4, 2007 predicts that a particle will most likely be found in the quantum mechanical “box” whose dimensions would be defined by that resonant wave.  However quantum mechanics treats particles as a one dimensional points and because it could be anywhere in it there would be an inherent uncertainty involved in determining the exact position of a particle in that “box”.

For examine the formula give above ( â–²xâ–²p  Â³ h / 2 ) tells us that uncertainty of measuring the exact position of the point in that “box” defined by its wavefunction would be equal to â–²xâ–²p  Â³ h / 2.   However because we are only interested in determining its exact position we can eliminate all references to its momentum.

However if we eliminate the momentum component from the uncertainty in a particle position become 6.626068 × 10^-34 meters or Planck’s constant.

As mentioned earlier the uncertainty involved in determining the exact position of a particle is because it is impossible to determine were in the “box” defined earlier the quantum mechanical point representing that particle is located.  However as mentioned earlier Planck’s constant tells us that one cannot determine the position of a particle to an accuracy greater that 6.626068 × 10^-34.  This suggest that Planck constant 6.626068 × 10^-34 defines the physical parameters or dimensions of that “box” because it defines the parameters of where in a given volume of space a quantum particle can be found.

In other words it defines a physical interpretation of Planck’s constant or 6.626068 × 10^-34 (kg*m2/s), and Heisenbergâ€s Uncertainty Principle by extrapolating the observable properties and laws of our three-dimensional environment to a fourth *spatial* dimension.

However it also gives one the ability to connect the probabilities associated with Schrödinger’s wave function to the observable reality of our three-dimensional environment.

As was mentioned one can conceptually derive the quantum mechanical properties of his function in terms of physical properties of a mater wave observed by Davisson and Germer by assuming that they are a result of resonant properties of four *spatial* dimensions.

Classical mechanics tell us that due to the continuous properties of waves the energy the article “Why is energy/mass quantized?” Oct. 4, 2007 associated with a quantum system would be distributed throughout the entire “surface” a three-dimensional space manifold with respect to a fourth *spatial* dimension.

For example Classical mechanics tells us that the energy of a vibrating or oscillating ball on a rubber diaphragm would be disturbed over its entire surface while the magnitude of those vibrations would decrease as one move away from the focal point of the oscillations. 

Similarly if the assumption that quantum properties of energy/mass are a result of vibrations or oscillations in a “surface” of three-dimensional space is correct then classical mechanics tell us that those oscillations would be distributed over the entire “surface” three-dimensional space while the magnitude of those vibrations would be greatest at the focal point of the oscillations and decreases as one moves away from it.

As mentioned earlier the article “Why is energy/mass quantized?” Oct. 4, 2007 shown a quantum object is a result of a resonant structure formed on the “surface” of a three-dimensional space manifold with respect to a fourth *spatial* dimension.

Yet Classical Wave Mechanics tells us resonance would most probably occur on the surface of the rubber sheet were the magnitude of the vibrations is greatest and would diminish as one move away from that point,

Similarly a particle would most probably be found were the magnitude of the vibrations in a “surface” of a three-dimensional space manifold is greatest and would diminish as one move away from that point.

This shows how one can eliminate infinities from our understanding of the quantum properties of energy/mass while at the same time allow one to connect those properties to the observable realities of our environment.

Later Jeff

Copyright Jeffrey O’Callaghan 2016

The post Infinities: what do they mean for Quantum theory. appeared first on Unifying Quantum and Relativistic Theories.

We think so.

Many including Albert Einstein and Erin Schrödinger, had difficulty accepting the “reality” of quantum mechanics because many of its concepts appear to contradict those of our observable universe.

For example in a quantum system Schrödinger’s wave equation defines the field properties of its environment and predicts the future distribution of a particle’s position only in terms of the abstract properties of probabilities.

However many including Einstein and Schrödinger define reality in terms of what they see or touch.
For example, Einstein used the observable “reality” of the interactions of electromagnetic energy with a photoelectric material to derive the quantum mechanical properties of energy/mass while using the observable properties of light in our three-dimensional environment to define his space-time universe.

In other words his conclusion that electromagnetic energy is quantized was based on the physical “reality” of the environment surrounding the photoelectric material and how electromagnetic energy interacted with it, not on the abstract probabilities associated with quantum fields.

However the abstract properties of probabilities share a common characteristic with Einstein space-time universe in that time or a space-time dimension have never be seen or touched and therefore they like the probability functions of quantum field theory are, by definition abstract quantities.

Fortunately they also have a common element in, as mentioned earlier the physically observable non-abstract properties of the *spatial* dimensions because the probabilities associated with Schrödinger’s wave equation are expressed in terms of the spatial properties of position.

Einstein gave us the ability to do this when used the equation E=mc^2 and the velocity of light to define the geometric properties of space-time because it allows one to convert a unit of displacement he associated with energy in a four dimensional space-time universe to an equivalent unit of spatial displacement in four *spatial* dimensions.  Additionally because the velocity of light is constant it is possible to defined a one to one correspondence between his space-time universe and one made up of four *spatial* dimensions.

In other words because he defined the geometric relationship between energy, mass, space and time in terms of the constant velocity of light means that one can quantitatively and qualitatively define a one to one between the properties of energy in a space-time universe to the physical properties of space four *spatial* dimensions.

The fact that one can use the Einstein’s equations to qualitatively and qualitatively derive the spatial properties of energy in a space-time universe in terms of four *spatial* dimensions is one bases for assuming, as was done in the article “Defining energy?” Nov 27, 2007 that all forms of energy can be derived in terms of a spatial displacement in a “surface” of a three-dimensional space manifold with respect to a fourth *spatial* dimension. 

One of the theoretical advantages of a modeling the existence of energy/mass on four *spatial* dimensions instead of four dimension space-time is it allows one to derive the “reality” of a quantum fields in terms of the observable non-abstract properties of our three-dimensional environment.

The physical “reality” of the field properties energy/mass in four *spatial* dimension was developed in the article “Electromagnetism in four *spatial* dimensions” Sept 27, 2007 where it was shown the forces associated with an electromagnetic field can be explained and predicted in terms of matter wave on field consisting of four *spatial* dimensions.

Briefly it showed that one can derive its field properties by extrapolating the observable non-abstract properties of a three-dimensional environment to a fourth *spatial* dimension.

For example a wave on the two-dimensional surface of water causes a point on that surface to be become displaced or rise above or below the equilibrium point that existed before the wave was present.  A force will be developed by the differential displacement of the surfaces, which will result in the elevated and depressed portions of the water moving towards or become “attracted” to each other and the surface of the water.

Similarly a matter wave on the “surface” of a three-dimensional space manifold with respect to a fourth *spatial* dimension would cause a point on that “surface” to become displaced or rise above and below the equilibrium point that existed before the wave was present.

Therefore observations  of our three dimensional “reality”, if extrapolated  to four *spatial* dimensions tells us the force developed by the differential displacements caused by a matter wave moving on a “surface” of three-dimensional space with respect to a fourth *spatial* dimension will result in its elevated and depressed portions moving towards or become “attracted” to each other.

This defines the causality of the attractive forces of unlike charges associated with the electromagnetic wave component of a photon in terms of a force developed by a differential displacement of a point on a “surface” of a three-dimensional space manifold with respect to a fourth *spatial* dimension.

However, it also provides a non-abstract mechanism for understanding why similar charges repel each other because observations of wave on the surface of water tell us that there is a direct relationship between the magnitudes of a displacement in its surface to the magnitude of the force resisting that displacement.

Similarly the magnitude of a displacement in a “surface” of a three-dimensional space manifold with respect to a fourth *spatial* dimension caused by two similar charges will be greater than that caused by a single one.  Therefore, similar charges will repel each other because the magnitude of the force resisting the displacement will be greater for two charges than it would be for a single charge.

One can define the causality of electrical component of electromagnetic radiation in terms of the energy associated with its “peaks” and “troughs” that is directed perpendicular to its velocity vector while its magnetic component would be associated with the horizontal force developed by that perpendicular displacement.

However, observations of our three dimensional environment tell us a horizontal force will be developed by that perpendicular or vertical displacement which will always be 90 degrees out of phase with it.  This force is called magnetism.

This is analogous to how the vertical force pushing up of on mountain also generates a horizontal force, which pulls matter horizontally towards the apex of that displacement.

This shows how one can explain and predict the continuous field properties of electromagnetism by extrapolating the observable non-abstract properties of our three dimensional environment to a matter wave moving on a “surface” of a three-dimensional space manifold with respect to a fourth *spatial* dimension.

However, as was shown in the article “The Photon: a matter wave?” Oct. 1, 2007 the quantum field properties of four *spatial* dimension can also be derived by extrapolating the observable non-abstract resonant properties of a three-dimensional environment to one consisting of four *spatial* dimension.

There are four conditions required for resonance to occur in a three-dimensional environment an object or substance with a natural frequency, a forcing function at the same frequency as the natural frequency, the lack of a damping frequency and the ability for the substance to oscillate spatial.

The existence of four *spatial* dimensions would give the continuous surface or field of three-dimensional space manifold (the substance) the ability to oscillate spatially with respect to a fourth *spatial* dimension thereby fulfilling one of the requirements for classical resonance to occur.

These oscillations would be caused by an event such as the decay of a subatomic particle or the shifting of an electron in an atomic orbital.  This would force the “surface” of a three-dimensional space manifold with respect to a fourth *spatial* dimension to oscillate with the frequency associated with the energy of that event.

Therefore, these oscillations in four *spatial* dimensions, would meet the requirements mentioned above for the formation of a resonant system or “structure” in space. 

Observations of a three-dimensional environment show the energy associated with resonant system can only take on the incremental or discreet values associated with a fundamental or a harmonic of the fundamental frequency of its environment.

Similarly the energy associated with resonant systems in four *spatial* dimensions could only take on the incremental or discreet values associated a fundamental or a harmonic of the fundamental frequency of its environment.

These resonant systems in four *spatial* dimensions are responsible for the incremental or discreet field energies associated quantum and electromagnetic field theories

This shows how one can define the “reality” of the continuous field associated with Schrödinger’s wave equation and a physical mechanism responsible for the creation of particles in that field in terms of the observable non-abstract “reality” of our three-dimensional environment.

Latter Jeff

Copyright 2013 Jeffrey O’Callaghan

The post The Geometry of Quantum Mechanics appeared first on Unifying Quantum and Relativistic Theories.

We have shown throughout this blog and its companion book “The Reality of the Fourth *Spatial* Dimension” there would be many theoretical advantages to defining space in terms four *spatial* dimensions instead of four-dimensional space-time.

One of them is that it would allow one to understand the classical origins of Heisenberg’s Uncertainty Principle by extrapolating observations of a three-dimensional environment to a fourth *spatial* dimension. 

For example In the article “Why is energy/mass quantized?” Oct. 4, 2007 it was shown it is possible to understand its quantum mechanical properties by extrapolating the laws of classical resonance in a three-dimensional environment to a matter wave on a “surface” of a three-dimensional space manifold with respect to a fourth *spatial* dimension.

Briefly it showed the four conditions required for resonance to occur in a classical environment, an object, or substance with a natural frequency, a forcing function at the same frequency as the natural frequency, the lack of a damping frequency and the ability for the substance to oscillate spatial would be meet by a matter wave in four *spatial* dimensions.

The existence of four *spatial* dimensions would give a matter wave the ability to oscillate spatially on a “surface” between a third and fourth *spatial* dimensions thereby fulfilling one of the requirements for classical resonance to occur.

These oscillations would be caused by an event such as the decay of a subatomic particle or the shifting of an electron in an atomic orbital. This would force the “surface” of a three-dimensional space manifold with respect to a fourth *spatial* dimension to oscillate with the frequency associated with the energy of that event.

The oscillations caused by such an event would serve as forcing function allowing a resonant system or “structure” to be established in four *spatial* dimensions.

Classical mechanics tells us the energy of a resonant system can only take on the discrete or quantized values associated with its resonant or a harmonic of its resonant frequency

Therefore the discrete or quantized energy of resonant systems in a continuous form of energy/mass would be responsible for the discrete quantized quantum mechanical properties of particles.

However, it did not explain how the boundaries of a particleâ€s resonant structure are defined.

In classical physics, a point on the two-dimensional surface of paper is confined to that surface.  However, that surface can oscillate up or down with respect to three-dimensional space.

Similarly an object occupying a volume of three-dimensional space would be confined to it however, it could, similar to the surface of the paper oscillate “up” or “down” with respect to a fourth *spatial* dimension.

The confinement of the “upward” and “downward” oscillations of a three-dimension volume with respect to a fourth *spatial* dimension is what defines the geometric boundaries of the “box” containing the resonant system the article “Why is energy/mass quantized?” associated with a particle.

However if this is true that one should be able to explain why the other properties of quantum systems are what they are in the same terms

For example in quantum mechanics, the uncertainty principle asserts that there a fundamental limit to the precision with which certain pairs of physical properties of a particle, such as position x and momentum p, can be simultaneously known.

However, Quantum Mechanics mathematically defines the position and momentum of a particle in terms of non-dimensional point.

Therefore according to the above concepts there would be an uncertainty in determining its position because that point could be found anywhere within the volume of the “box” mentioned above.

Similarly there would be an uncertainty in measuring its momentum, again because quantum mechanics defines movement in terms of a non dimensional point.  Therefore before one could determine a particle’s momentum one would have to know the exact position of the “end” points one use to measure its velocity.  However, as mentioned above that non dimension point representing a particle could be found anywhere in the box containing the resonant structure that define a particle in the article “Why is energy/mass quantized?“  Therefore one could not determine its exact velocity and momentum because there will always be an uncertainty as to where the non dimensional point representing a particle is in the box when the measurement was taken

The reason why one cannot simultaneously measure both with complete accuracy is because the act of measure its momentum or position requires one to access different segments the “box” containing the one dimensional point particle.

For example if one wants to make the most accurate measurement possible of its momentum internal to the box one would have to measure the time it took for it to transverse a given segment of it.  However this means that one could not determine its position because it would be changing through the entire time that it took it to transverse that portion of the box.

However if one wanted to make the most accurate measurement possible of its position internal to the box it would have to be stationary with respect to the box’s geometry meaning that one could not determine its monument because it would not be moving.  Since these two measurements required one to access different segments of a particles geometry they are mutually exclusive. 

Therefore one cannot simultaneously measure a particle position x and momentum p with complete accuracy.

This defines in terms of classical mechanics why there is a limit to the precision with which certain pairs of physical properties of a particle, such as position x and momentum p, can be simultaneously known.

Later Jeff

Copyright Jeffrey O’Callaghan 2012

The post A classical interpretation of Heisenberg’s Uncertainty Principal appeared first on Unifying Quantum and Relativistic Theories.

One is that it would allow for understanding of the physical significance of Planck’s constant in terms of the laws of classical physics.

In the article “Why is energy/mass quantized?” Oct. 4, 2007 it was shown it is possible to explain and predict the quantum mechanical properties of energy/mass by extrapolating the laws of classical resonance in a three-dimensional environment to a matter wave on a “surface” of a three-dimensional space manifold with respect to a fourth *spatial* dimension.

Briefly it showed the four conditions required for resonance to occur in a classical environment, an object, or substance with a natural frequency, a forcing function at the same frequency as the natural frequency, the lack of a damping frequency and the ability for the substance to oscillate spatial would be meet by a matter wave in an environment of four *spatial* dimensions.

The existence of four *spatial* dimensions would give a matter wave the ability to oscillate spatially on a “surface” between a third and fourth *spatial* dimensions thereby fulfilling one of the requirements for classical resonance to occur.

These oscillations would be caused by an event such as the decay of a subatomic particle or the shifting of an electron in an atomic orbital.  This would force the “surface” of a three-dimensional space manifold with respect to a fourth *spatial* dimension to oscillate with the frequency associated with the energy of that event.

The oscillations caused by such an event would serve as forcing function allowing a resonant system or “structure” to be established in four *spatial* dimensions.

Classical mechanics tells us the energy of a resonant system can only take on the discrete or quantized values associated with its resonant or a harmonic of its resonant frequency

This means that one can theoretically derive the quantum mechanical properties of Schrödinger’s wave function in terms of the physicality of resonant properties of four *spatial* dimensions if one assumes as is done here that its mathematical properties are representative of wave moving on a “surface” of a three-dimensional space manifold with respect to a fourth *spatial* dimension.

However it also gives one the ability to understand the physical meaning of Planck’s constant or 6.626068 × 10^-34 (kg*m2/s) by extrapolating the laws of classical physics in a three-dimensional environment to a fourth *spatial* dimension.

In classical physics, a point on the two-dimensional surface of paper is confined to that surface.  However, that surface can oscillate up or down with respect to three-dimensional space. 

Similarly an object occupying a volume of three-dimensional space would be confined to it however, it could, similar to the surface of the paper oscillate “up” or “down” with respect to a fourth *spatial* dimension.

The confinement of the “upward” and “downward” oscillations of a three-dimension volume with respect to a fourth *spatial* dimension is what defines the geometric boundaries or the “box” containing the wave or wave function the article “Why is energy/mass quantized?” Oct. 4, 2007 associated with a particle. 

Planck’s constant is one of fundamental components of Quantum Physics and along with Heisenbergâ€s Uncertainty Principle it defines the uncertainty in the ability to measure more than one quantum variable at a time.  For example attempting to measure an elementary particleâ€s position (â–²x) to the highest degree of accuracy leads to an increasing uncertainty in being able to measure the particleâ€s momentum (â–²p) to an equally high degree of accuracy.  Heisenbergâ€s Principle is typically written mathematically as â–²xâ–²p  ³ h / 2  where h represents Planck constant

As mentioned earlier the resonant wave that corresponds to the quantum mechanical wave function defined in the article “Why is energy/mass quantized?” predicts that a particle will most likely be found in the quantum mechanical “box” whose dimensions would be defined by that resonant wave.  However quantum mechanics treats particles as a one dimensional points and because it could be anywhere in it there would be an inherent uncertainty involved in determining the exact position of a particle in that “box”.

For examine the formula give above ( â–²xâ–²p  ³ h / 2 ) tells us that uncertainty of measuring the exact position of the point in that “box” defined by its wavefunction would be equal to â–²xâ–²p  ³ h / 2.   However because we are only interested in determining its exact position we can eliminate all references to its momentum.

However if we eliminate the momentum component from the uncertainty in a particle position become 6.626068 × 10^-34 meters or Planck’s constant.

As mentioned earlier the uncertainty involved in determining the exact position of a particle is because it is impossible to determine were in the “box” defined earlier the quantum mechanical point representing that particle is located.  However as mentioned earlier Planck’s constant tells us that one cannot determine the position of a particle to an accuracy greater that 6.626068 × 10^-34.  This suggest that Planck constant 6.626068 × 10^-34 defines the physical parameters or dimensions of that “box” because it defines the parameters of where in a given volume of space a quantum particle can be found.

This shows how one can define and understand the physicality of Planck’s constant by extrapolating the laws of classical physics in three-dimensional environment to a fourth *spatial* dimension if one assumes as is done here that the quantum mechanical properties of the wave function are cause by a resonant structure in four *spatial* dimensions.

Later Jeff

Copyright Jeffrey O’Callaghan 2012

The post The physical significance of Planck’s constant appeared first on Unifying Quantum and Relativistic Theories.