Schwinger (Dyon) Fields – links to neutrino fields, gluon fields, particle fields, mass fields, Higgs fields, vacuum fields, gravitational fields

Schwinger (Dyon) Fields – links to neutrino fields, gluon fields, particle fields, mass fields, Higgs fields, vacuum fields, gravitational fields

Maury Goodman (anl.gov) has a wonderful Neutrino newsletter “Long Baseline news” for Aug 2024. #DUNEScience The last link is Leonid Slad’s paper.

Maury’s August newsletter is at https://www.hep.anl.gov/ndk/longbnews/2408.html and the Index is at https://www.hep.anl.gov/ndk/longbnews/index.html

For many years I have been trying to find a decent model of neutrino generation and detection and to find the relation between neutrinos, the gravitational potential, and gluon plasma (as a substance with very specific properties that can be modeled and give reliable results. So when I read Leonid Slad’s paper today, it instantly simplified many things for me.

[ Leonid should not do the relativistic corrections in every equation that way. That can be simplified in a model for calculations. The voxel level properties can be separated and “relativistic” only used at the interfaces and where gradients are strong.  The “relativistic” effects are several things that are properties of “the vacuum as a dyon field”. CERN made it much too complicated because they have too many people getting paid and a few people cannot keep track of that and make all the funding decisions and the directions.)

[ It is Leonid (and others)  whole body of work, a larger effort, that matters. I am trying to map it out. But they could adapt and meet halfway if Moscow is not destroyed in a useless war. “Work together” is a lot better than invade and kill. ]

Logic and numbers related to solar neutrinos by Leonid M Slad at https://arxiv.org/abs/2408.06041# (12 Aug 2024)

Julian Schwinger made up the name. But I am generalizing it. A dyon field is any regions (voxels) with known or modeled charge and magnetic structure. Any region with moving positive and negative charges however small or fast. Dyon fields can be made out of gluon plasma. A region can wrap a “particle” or any set of  high energy density (by volume) regions. Then “collide that dyon” or “store those dyons” or “make a mole of dyons with these properties” or “store the output of that energy generator in this type of dyon and ship it to Moon Base 1.”

The vacuum can be modeled as overlapping dyon fields, however temporary or small. The Higgs field can be nicely modeled in terms of potentials, gradients, charge, flows, rigidity, and many other properties — using electromagnetic units, which can be converted into any other units.

I am trying to map out “the standard model” but legions of individuals, all focused on their own things, did not map the whole and put it where every human can see and understand it.  “The vacuum” is NOT clearly delineated and mapped on the Internet.  And many things that do apply are ignored or forgotten or left out.  It has to be taken as a whole, not “what one human can do in a few hours” or years. Or “we like our old models because we had to go that way”.

The biggest reason Schwinger could not get people to work together was they all insisted on using only what they were familiar with. A dyon region is a plasma.  A plasma can be stored as a dyon field.  The reason for remembering that it has electric and magnetic field and those are dynamic is to remember that every voxel is important and might make a critical difference.  A dyon can have a 3D basis set of many forms. A dyon remembers the legacy of Schwinger.  It is a useful unique tag on the Internet like #dyon or #dyons or #DyonFields or #SchwingerDyonFields

Since anything with a neutron or where protons and electrons are created by lasers or collisions will have internal electric charge and magnetic gradients, that means pretty much everything, even if you have to excite some of the states by using multiple crossed beams and KiloTelsa and MegaTesla pulsed fields (high harmonic gain lasers) and radioactive beam sources.
Any moving particle will likely be “dyonic” part of the time. Regions of “binding energy” have their own field, but it has to use standard units. Nothing should be so locked down and fought over it cannot be adapted and updated. Dyons can oscillate and store “states”. They can be generated, detected, identified, counted, filters, focused, stored, converted, used as raw materials, used as products.
Any dynamic gravitational potential can be stored as a dyon field object. And, itts gradients and time derivatives, effects on clocks and reactions calculated. The non-linear, “viscous”, “turbulence”, “vorticity”, “vortex”, “relativistic” properties of the potential field, or the vacuum dyon field (as computer objects) can be calculated and applied.
 
https://en.wikipedia.org/wiki/Dyon.
 
Twisted particles in heavy-ion collisions by Alexander J. Silenko, Pengming Zhang, Liping Zou at https://arxiv.org/abs/2101.03620
 
Equation of spin motion for a particle with electric and magnetic charges and dipole moments by Alexander J. Silenko at https://arxiv.org/abs/2309.04985
 
Spin rotation as an element of polarization experiments on elastic electron-proton scattering by Leonid M Slad at https://arxiv.org/abs/0904.1671

I have been telling groups “it is electromagnetism all the way down” and I did not know that Julian Schwinger wanted to go that direction. I know almost exactly what it means for new global industries, in great detail.  But I am just one person, so I can only try to leave some breadcrumbs and hope someone notices.  These are my rough notes this morning, just to post it where it might be seen and remembered and maybe shared.

It changes the fusion models by greatly narrowing the possible states and fates of the reactants and products. It is not a vague “cross-section” but deliberate and specific instructions for assembling and using energy stored in stable states of the vacuum, the Higgs dyon field, the gravitational potential field. Where “stable” means anything you can make and use reliably. A “field” to me is usually dynamic 3D volumetric with all the data, models and people attached in a useful form.
 
Richard Collins, The Internet Foundation
Richard K Collins

About: Richard K Collins

The Internet Foundation Internet policies, global issues, global open lossless data, global open collaboration


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