{"id":12248,"date":"2014-02-15T06:18:56","date_gmt":"2014-02-15T10:18:56","guid":{"rendered":"http:\/\/www.theimagineershome.com\/blog\/?p=12248"},"modified":"2018-12-15T10:59:33","modified_gmt":"2018-12-15T14:59:33","slug":"mass-from-first-principals","status":"publish","type":"post","link":"https:\/\/www.theimagineershome.com\/blog\/mass-from-first-principals\/","title":{"rendered":"Mass from first principles"},"content":{"rendered":"

Bohr summarized the complementary principal of quantum mechanics as follows:<\/font><\/p>\n

“However far the quantum physical phenomena transcend the scope of classical physical explanation, the account of all evidence must be expressed in classical terms. The argument is simply that by the word “experiment” we refer to a situation where we can tell others what we have learned and that, therefore, the account of the experimental arrangements and of the results of the observations must be expressed in unambiguous language with suitable application of the terminology of classical physics.<\/font><\/i><\/p>\n

This crucial point…implies the impossibility of any sharp separation between the behavior of atomic objects and the interaction with the measuring instruments which serve to define the conditions under which the phenomena appear…. Consequently, evidence obtained under different experimental conditions cannot be comprehended within a single picture, but must be regarded as complementary in the sense that only the totality of the phenomena exhausts the possible information about the object.”<\/font><\/i><\/p>\n

In other words he did not think that it was possible to use classical concepts to integrate the wave and particle characteristics of a quantum particle into a single picture therefore he felt that there exits a physical division between the macroscopic world of classical objects and the microscopic world of quantum particles.  <\/font><\/p>\n

However this may not be the true and one can understand why if one views the universe in terms of four *spatial* dimensions instead of four dimensional space-time.<\/font><\/i><\/p>\n

(The reason will become obvious later.)<\/font><\/i><\/p>\n

Einstein gave us the ability to do this when he used the velocity of light to define the geometric properties of space-time because it allows one to convert a unit of time in his space-time <\/span>universe to a unit of a *spatial* dimension identical to those in our three-dimensional universe .<\/font>  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. <\/font><\/font><\/p>\n

In other words by mathematically defining the geometric properties of a space-time universe in terms of the constant velocity of light he provided a qualitative and quantitative means of redefining it in terms of the geometry of four *spatial* dimensions. <\/font><\/span><\/p>\n

The fact that one can use Einstein’s equations to qualitatively and quantitatively redefine the curvature in space-time he associated with energy in terms of four *spatial* dimensions is one bases for assuming as was done in the article \u00e2\u20ac\u0153<\/font>Defining energy?<\/font><\/a>\u00e2\u20ac\u009d 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.  <\/font><\/p>\n

One of the advantage to doing is that allows one to understand the wave particle duality of energy\/mass or its complementary property in terms of the concepts of classical physics. <\/font><\/p>\n

For example the article, “<\/font>Why is energy\/mass quantized?<\/font><\/a>” Oct. 4, 2007 showed that one can explain and understand the physicality of its particle properties in terms of the classical concept of waves by extrapolating the laws of resonance in a three-dimensional environment to a matter wave moving on \u00e2\u20ac\u0153surface\u00e2\u20ac\u009d of a three dimensional space manifold with respect to a fourth *spatial* dimension.  It also explains why all energy must be quantized or exist in these discrete resonant systems when observed. <\/font><\/p>\n

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 occur in a matter wave moving in four *spatial* dimensions. <\/font><\/p>\n

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. <\/font><\/p>\n

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. <\/font><\/p>\n

However, 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. <\/font><\/p>\n

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. <\/font><\/span><\/p>\n

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. <\/font><\/span><\/p>\n

Therefore these resonant systems in would be responsible <\/font>incremental or discreet energy associated with quantum mechanical systems.<\/font><\/font><\/p>\n

This allows one to define the particle properties of energy\/mass in terms of the classical concepts of a wave.<\/font><\/p>\n

However, one can define its wave properties in terms of the classical concepts of a particle in terms of the boundaries of its resonant structure. <\/font><\/p>\n

For example 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.  <\/font><\/p>\n

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. <\/font><\/p>\n

The confinement of the “upward” and “downward” oscillations of a three-dimension volume with respect to a fourth *spatial* dimension is what defines the spatial boundaries of the resonant system associated with a particle in the article “<\/font>Why is energy\/mass quantized?<\/font><\/a>“<\/font><\/p>\n

However <\/font>it also provides the ability to understand the inseparability of the wave and particle properties of energy\/mass because it clearly demonstrates how one is depend on the other.<\/font><\/i><\/font><\/p>\n

However it also explains why quantum systems either display the properties of a particle or a wave when measured because if one wants to measure the total energy contained in a given volume of space one will observe it as a particle while if one want to measure how it is propagated through space one must observe its wave properties.<\/font><\/p>\n

Additionally it defines a classical reason why particles sometimes behave like wave and sometimes like particle and why it is impossible simultaneously observe them.<\/font><\/i><\/p>\n

As shown earlier the energy contained in a quanta of space associated with a particle would be defined by the energy associated with the wavelength of its resonate structure.  In other words to observe or measure the particle properties of a given volume of space one has to sample all of its energy leaving nothing of its wave component to measure.  Similarly if one wants to observe or measure fully the wave energy of a quantum of space one would have to sample all of its energy leaving none of its particle properties. <\/font><\/p>\n

(If one does not want to observe all of the energy in a given volume of space then one would expect that the difference would be made up by the emission of a photon or other particle whose energy would correspond to that difference.)<\/font><\/p>\n

The reason why one cannot simultaneously measure both its wave and particle properties is because as mentioned the energy of a particle is defined by the wave properties of its resonant structure.  Since the resonant system that defines a particle is the smallest unit of its resonate structure if one measures its particle properties there would be no wave energy left for measuring its wave proprieties while if someone measure its wave energy there would be no energy left to support its particle properties. Therefore making one of these measurements precludes the other. <\/font><\/p>\n

This demonstrates how one can integrate the wave and particle characteristics of a quantum particle into a single picture and why the  physical division between the macroscopic world of classical objects and the microscopic world of quantum particles as was assumed by Bohr many not exist.  <\/font><\/p>\n

Later Jeff<\/font><\/p>\n

Copyright Jeffrey O’Callaghan 2014<\/font><\/p>\n","protected":false},"excerpt":{"rendered":"

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