Slides from my first Physics Lecture, and a New Draft Paper Summarizing the Experimental Points of Contact which Affirm my Work

This past week I gave my first physics lecture on the research in my recent four published papers establishing that proton and neutrons are actually a particular type of magnetic monopole (based on a theory called Yang-Mills because those are the names of the two fellows who invented its foundations).  In the lecture, I consolidated all four of my papers totaling about 140 pages into a 70 minute lecture (50 minutes talk, 20 minutes Q&A discussion) and 64 slides which you can download from Physics Lecture Slides.

It would probably take someone a couple of weeks to read through and thoroughly understand my four papers.   The slides were designed to allow someone to assimilate the same information within a couple of hours.  Please take a look.

Also, I prepared a new paper which you may read at Fitting the 2H, 3H, 3He, 4H Binding Energies 3  which in ten pages lays out the multiple relationships I have found which very clearly connect to experimental data that had never before been explained.  This is the “tip of the iceberg” in terms of the multiple ways in which nature herself validates my theoretical work at the parts-per-million level.   My hope is that people in the physics community will see these results, realize that there is something real here, and then take the time to backtrack to understand the theoretical foundations that got me to that point.  A sort of “inversion” of my work to lead with the experimental results in order to catalyze interest.  Everything in this paper by the way, is simple arithmetic (as in, numbers calculated and compared to other numbers), and about the only complexity is that you need to understand a tiny bit about matrix multiplication (like that the “Trace” of a square matrix is just the sum of all the entries long its upper left to lower right diagonal).  If you do not want to even sort through the matrix stuff, then just look at equations (14) through (20).  These are pure numbers, and you will see how close I get to the experimental data each and every time.  Nobody has ever before explained this experimental data with such high precision!

People, I am usually careful not to toot too loudly about my work.  But I have to say that this is real, it is fundamental, and it will revolutionize nuclear and particle theory.  The question is no longer if, but when.  The discoveries have been made and they are in print and all they need is attention from the right places.  My “lab notes” and related work will soon spark a “scientific revolution” toward which I have been working for over 40 years.  Real results in hand, I am now doing all that I can to make that happen sooner rather than later.  I welcome any help or support my friends can provide in making that happen.

Jay

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My four recent peer-reviewed papers about Magnetic Monopole Baryons are now all published and online

I wanted to let you know that my recent second, third and fourth peer-reviewed papers were all published on April 30.  These papers, in order of logical development, are:

2)  J. Yablon, “Predicting the Binding Energies of the 1s Nuclides with High Precision, Based on Baryons which Are Yang-Mills Magnetic Monopoles,” Journal of Modern Physics, Vol. 4 No. 4A, 2013, pp. 70-93. doi: 10.4236/jmp.2013.44A010.

Link: http://www.scirp.org/journal/PaperInformation.aspx?PaperID=30817

3)  J. Yablon, “Grand Unified SU(8) Gauge Theory Based on Baryons which Are Yang-Mills Magnetic Monopoles,” Journal of Modern Physics, Vol. 4 No. 4A, 2013, pp. 94-120. doi: 10.4236/jmp.2013.44A011.

Link: http://www.scirp.org/journal/PaperInformation.aspx?PaperID=30822

4)  J. Yablon, “Predicting the Neutron and Proton Masses Based on Baryons which Are Yang-Mills Magnetic Monopoles and Koide Mass Triplets,” Journal of Modern Physics, Vol. 4 No. 4A, 2013, pp. 127-150. doi: 10.4236/jmp.2013.44A013.

Link: http://www.scirp.org/journal/PaperInformation.aspx?PaperID=30830

The “Special issue on High Energy Physics” in which the foregoing all appear is at: http://www.scirp.org/journal/jmp/

Also, the very first paper in which is is all rooted was published a couple of months ago, but finally went online about ten days ago.  This paper may be downloaded at:

1)  Yablon, J. R., Why Baryons Are Yang-Mills Magnetic Monopoles, Hadronic Journal, Volume 35, Number 4, 401-468 (2012)

Link: http://www.hadronicpress.com/issues/HJ/VOL35/HJ-35-4.pdf

If you want to quickly understand the original paper #1, which is 67 pages, I suggest that you start by reading the introductory section in paper #2, which is a three page encapsulation of paper #1.  Overall, this introductory section of paper #2 is the best point entry to understanding my recent research.  I am happy to answer questions or engage in discussions online.

Best to all,

Jay

My first published paper “Why Baryons Are Yang-Mills Magnetic Monopoles” at Hadronic Journal, Volume 35, Number 4, 399-467 (2012)

My first paper “Why Baryons Are Yang-Mills Magnetic Monopoles” has now been published in Hadronic Journal, Volume 35, Number 4, 399-467 (2012). Though the Hadronic Journal has not yet put this issue online, I have a hardcopy of this and have uploaded a scan at the link below:

Hadronic Journal, Volume 35, Number 4, 399-467 (2012)

As I have advised on some earlier blog entries, I have two more accepted papers which will be published next month (April 2013) in the Journal of Modern Physics, Special Issue on High Energy Physics.

Jay

Two New Papers: Grand Unified SU(8) Gauge Theory Based on Baryons which are Yang-Mills Magnetic Monopoles . . . and . . . Predicting the Neutron and Proton Masses Based on Baryons which are Yang-Mills Magnetic Monopoles and Koide Mass Triplets

I have not had the chance to make my readers aware of two new recent papers. The first is at Grand Unified SU(8) Gauge Theory Based on Baryons which are Yang-Mills Magnetic Monopoles and has been accepted for publication by the Journal of Modern Physics, and will appear in their April 2013 “Special Issue on High Energy Physics.”  The second is at Predicting the Neutron and Proton Masses Based on Baryons which are Yang-Mills Magnetic Monopoles and Koide Mass Triplets and is presently under review.

The latter paper on the neutron and proton masses fulfills a goal that I have had for 42 years, which I have spoken about previously in the blog, of finding a way to predict the proton and neutron masses based on the masses of the fermions, specifically, the electron and the up and down quark (and as you will see , the Fermi vev).  Between this latter paper and my earlier paper at Predicting the Binding Energies of the 1s Nuclides with High Precision, Based on Baryons which are Yang-Mills Magnetic Monopoles, I have made six distinct, independent predictions with accuracy ranging from parts in 10,000 for the neutron plus proton mass sum, to an exact relationship for the proton minus neutron mass difference, parts per 100,000 for the 3He binding energy, parts per million for the for the 3H and 4He binding energies, and parts per ten million for the 2H binding energy (based on the proton minus neutron mass difference being made exact).  I have also proposed in the binding energies paper, a new approach to nuclear fusion, known as “resonant fusion,” in which one bathes hydrogen in gamma radiation at certain specified frequencies that should catalyze the fusion process.

In addition, the neutron and proton mass paper appears to also provide a seventh prediction for part of the determinant of the CKM generational mixing matrix.  And the GUT paper establishes the theoretical foundation for exactly three fermion generations and the observed mixing patterns, answering Rabi’s question “who ordered this?”.

All of this in turn, is based on my foundational paper Why Baryons Are Yang-Mills Magnetic Monopoles.  Taken together, these four papers place nuclear physics on a new foundation, with empirical support from multiple independent data points.  The odd against six independent parts per 10^6 concurrences being mere coincidence are one in 10^36, and I now actually have about ten independent data points of very tight empirical support.  If you want to start learning nuclear physics as it will be taught around the world in another decade, this is where you need to start.

Best to all,

Jay