Validations

_ _ _ _ _ _ _ _

	At present we recognize eight principles necessary for elementary matter to exist as metaparticles in two forms.
	Red identifies principles about which we have come upon no validating indications in scientific sources.
	The four principles tagged in blue are either accepted or in the process of theoretical development and testing -- by particle physics - as indicated in multiple references during recent months. Consequently we can claim sufficient validating indications that in these cases, metaparticle principles show definite parallels with progressive changes in particle physics.

EIGHT PRINCIPLES
PRODUCING AND MAINTAINING METAPARTICLES

1 -

The Dynamic Field

As the ultimate source of matter, the Field will in the foreseeable future remain of no interest to science. Though matter comes from it, it is not by strict definition material. It is an indefinable, enduring "substance" characterizable by an absolute "dynamic stillness".

2 -

Divergent Balance

This is produced by the action of a "separative" force which precipitates divided points of energy out of the homogeneous Field and into the spatial universe of differences, multiplicity, and opposites. Still too metaphysical for Science.

3 -

Bipolar Diametric Structure

One metaparticle solution to the problem of maintaining both stability and spin in an elementary particle. Physics is as yet far from interested in employing improved colliders to establish the existence of point-particles in hyperspace that could fill the role of "greater poles" in the metaparticle structure. But they have at long last settled on a structural concept that escapes the impossibility of attributing spin to a non-dimensional point.

What physics has now introduced is a single-point particle that unexplainedly possesses the attribute of intrinsic angular momentum. An (invisible) sphere of tiny particles surrounds the monopolar point of the electron. This sphere's fluctuations either sustain or provide the electron's spin. Origin of the sphere is not explained, but the idea goes a big step ahead of the old one -- and we claim (futilely of course) the metaparticle theory played a suggestive part in that.

4 -

Bipolar Axial Rotation

Though there may be instances of such rotation in particles unfamiliar to us, we do know that binary rotation around a center of gravity is commonplace in astronomy. To this degree, then, the metaparticle's rotation on an axis through its diameter is validated as a well known scientific principle.

5 -

Spin Angular Momentum

In every contact I made with physicists during the years of Metaparticles' development I called attention to the illogic of attributing spin to a point particle. Of course this was belaboring the obvious; they already knew that. Particle physicists were at that time admittedly too occupied with other concerns to address the need for particle structure. Still, it is now very gratifying to see the concept of spin being expanded to become interior rotation in particles. Angular momentum is a basic fact in physics and is necessary to the divergent balancing system in the metaparticle. The major problem is theorizing an attractive force to balance it.

6 -

Diametric Unifying Force

An hypothesis for which we have no specific evidence. However, there must be a force along the diameter of an electron to counteract or balance angular momentum and preserve the integrity of the particle's form. To propose that such a force could be electromagnetic would require (it seems to me) that the greater pole should be carrying a positive charge reacting with the negative charge of the lesser pole. Such would possibly offset angular momentum, but should also cause electron/positron reactions between similar particles.

The homogeneous unity of the Dynamic Field has been postulated as cause of the strong attractive force needed for balance. The theory makes it clear that quantities of differing energy intensities derived directly from the Dynamic Field always reside in each pole of the metaparticle. It is accordingly a rational hypothesis to suppose that such a fundamental force could be active in an enduring tension towards reuniting the poles to match the original intensity of the Field, while at the same time offsetting angular momentum. Conversely the latter prevents such restoration; hence divergent balance.

7 -

Two-dimensional Dynamic Disk

We also can provide no specific evidence that a line of limited length, occupied by sufficiently strong forces, can result in an empirically perceptible disk when rotated on a midway axis. But we suspect the insufficiency of our knowledge, as well as our research, could be responsible. Such a disk might be considered imaginary and yet cause very real effects. The causative element in forming a dynamic disk is not bipolar rotation alone; that must be accompanied by a strong enough cohesive, attractive force operating along the metaparticle diameter.

8 -

Gyroscopic Precession Causing a Second Axis of Rotation in the Metaparticle

If there is any metaparticle principle that science might someday grant as having been uniquely suggested by our theory, it is the augmented, spherical form of the electron. This was a feature of the theory since it was first illustrated and circulated, along with computer simulation charts, in the late seventies.

The point-position sequences revealed by Charles Bueker's charts in Figs 5 and 6 (Section on 3-D alternate form) provided for me the dawn of understanding the basis on which quantum mechanics is able to do the probability predictions on which so many particle experiments have come to depend.

However, what is probably our best validation indicator came in 2001, when Brookhaven National Laboratory announced that precession had been observed in the spin-rotation of a muon (heavier electron). Gyroscopic precession marks the beginning of secondary rotation in a spinning perimeter; it implies the creation of a dynamic sphere caused by the continuation of that precessional spinning.

Brookhaven's releases on the Internet revealed little of detail but intimated that such discovery might challenge the Standard Model of particle physics. For us...that qualifies as being Very Good News.

_ _ _ _ _ _ _ _

Until it becomes further developed by the science of physics, the Metaparticle Theory remains only an introductory exposition. Its goal is to link an ultimate source of motion and energy with basic particle structures composing the matter of universal existence.

There must have been other attempts to make such a connection. But I know of none resulting in particle structures that offer testable solutions in the many problem areas covered by the term wave/particle duality.

Particle Physics has for quite awhile been turning some of its attention towards new particle structures and functions that seem to be demanded by their own experiments. Our "validation" listings include four blue-tagged examples where our theorizings and those of professionals working in related fields show significant parallels. The two are of course very different in root concepts, but we are still rendered optimistic by the longterm outlook.

1 -		The Dynamic Field As the ultimate source of matter, the Field will in the foreseeable future remain of no interest to science. Though matter comes from it, it is not by strict definition material. It is an indefinable, enduring "substance" characterizable by an absolute "dynamic stillness".
2 -		Divergent Balance This is produced by the action of a "separative" force which precipitates divided points of energy out of the homogeneous Field and into the spatial universe of differences, multiplicity, and opposites. Still too metaphysical for Science.
3 -		Bipolar Diametric Structure One metaparticle solution to the problem of maintaining both stability and spin in an elementary particle. Physics is as yet far from interested in employing improved colliders to establish the existence of point-particles in hyperspace that could fill the role of "greater poles" in the metaparticle structure. But they have at long last settled on a structural concept that escapes the impossibility of attributing spin to a non-dimensional point. What physics has now introduced is a single-point particle that unexplainedly possesses the attribute of intrinsic angular momentum. An (invisible) sphere of tiny particles surrounds the monopolar point of the electron. This sphere's fluctuations either sustain or provide the electron's spin. Origin of the sphere is not explained, but the idea goes a big step ahead of the old one -- and we claim (futilely of course) the metaparticle theory played a suggestive part in that.
4 -		Bipolar Axial Rotation Though there may be instances of such rotation in particles unfamiliar to us, we do know that binary rotation around a center of gravity is commonplace in astronomy. To this degree, then, the metaparticle's rotation on an axis through its diameter is validated as a well known scientific principle.
5 -		Spin Angular Momentum In every contact I made with physicists during the years of Metaparticles' development I called attention to the illogic of attributing spin to a point particle. Of course this was belaboring the obvious; they already knew that. Particle physicists were at that time admittedly too occupied with other concerns to address the need for particle structure. Still, it is now very gratifying to see the concept of spin being expanded to become interior rotation in particles. Angular momentum is a basic fact in physics and is necessary to the divergent balancing system in the metaparticle. The major problem is theorizing an attractive force to balance it.
6 -		Diametric Unifying Force An hypothesis for which we have no specific evidence. However, there must be a force along the diameter of an electron to counteract or balance angular momentum and preserve the integrity of the particle's form. To propose that such a force could be electromagnetic would require (it seems to me) that the greater pole should be carrying a positive charge reacting with the negative charge of the lesser pole. Such would possibly offset angular momentum, but should also cause electron/positron reactions between similar particles. The homogeneous unity of the Dynamic Field has been postulated as cause of the strong attractive force needed for balance. The theory makes it clear that quantities of differing energy intensities derived directly from the Dynamic Field always reside in each pole of the metaparticle. It is accordingly a rational hypothesis to suppose that such a fundamental force could be active in an enduring tension towards reuniting the poles to match the original intensity of the Field, while at the same time offsetting angular momentum. Conversely the latter prevents such restoration; hence divergent balance.
7 -		Two-dimensional Dynamic Disk We also can provide no specific evidence that a line of limited length, occupied by sufficiently strong forces, can result in an empirically perceptible disk when rotated on a midway axis. But we suspect the insufficiency of our knowledge, as well as our research, could be responsible. Such a disk might be considered imaginary and yet cause very real effects. The causative element in forming a dynamic disk is not bipolar rotation alone; that must be accompanied by a strong enough cohesive, attractive force operating along the metaparticle diameter.
8 -		Gyroscopic Precession Causing a Second Axis of Rotation in the Metaparticle If there is any metaparticle principle that science might someday grant as having been uniquely suggested by our theory, it is the augmented, spherical form of the electron. This was a feature of the theory since it was first illustrated and circulated, along with computer simulation charts, in the late seventies. The point-position sequences revealed by Charles Bueker's charts in Figs 5 and 6 (Section on 3-D alternate form) provided for me the dawn of understanding the basis on which quantum mechanics is able to do the probability predictions on which so many particle experiments have come to depend. However, what is probably our best validation indicator came in 2001, when Brookhaven National Laboratory announced that precession had been observed in the spin-rotation of a muon (heavier electron). Gyroscopic precession marks the beginning of secondary rotation in a spinning perimeter; it implies the creation of a dynamic sphere caused by the continuation of that precessional spinning. Brookhaven's releases on the Internet revealed little of detail but intimated that such discovery might challenge the Standard Model of particle physics. For us...that qualifies as being Very Good News.