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

Accepted for Publication: Why Baryons Are Yang-Mills Magnetic Monopoles!

I am very pleased to report that the paper linked below, “Why Baryons Are Yang-Mills Magnetic Monopoles,” has been accepted for publication in Number 4, Volume 35, 2012 pp 401-468 of the Hadronic Journal.  This is due to be released in early January, 2013.

Why Baryons Are Yang-Mills Magnetic Monopoles Final for Publication

As you can see from elsewhere in this blog and in my various newsgroup posts, I have been advocating since 2005, the view that protons and neutrons and other baryons are Yang-Mills magnetic monopoles.  In this paper, I have finally developed the empirical proof, by predicting nuclear binding energies between such monopoles which accord with empirical binding data within a fraction of a percent, and by explaining how the nuclear binding energies relate to the energies which confine quarks within their respective nucleons.

If you want to start somewhere other than at the beginning, go to page 61 where you will see how I derive the up and down quark masses to six digit in MeV accuracy based on the electron rest mass and the deuteron binding energy, and where I show a predicted maximum available binding energy for ^56Fe of 493.028394 MeV.  The empirical data show that this nucleus has an empirical binding energy of 492.253892 MeV, which means that ^56Fe utilizes 99.8429093% of the energy predicted to be available, for actual binding.  The remaining 0.16% is used to continue to confine quarks within the nucleons that comprise ^56Fe, and this utilization of available binding energy is the maximum among all of the known nuclei, and sets the boundary between fusion and fission physics.

I believe that this will become big news as this work gains exposure and people begin to see what problems have been solved here.

Happy holidays to all!

Jay