One Paper that limits the axials forces right hand neutrinos and one that doesn't

Many theorys predicate right handed neutrino states, with different masses to the standard neutrinos. They are also known as sterile neutrino as they interact with no known force. Our axial force theory also has right handed neutrinos, which we don't call sterile as they interact with the axial force. During beta decay they a produced with fraction, of one axial force constant of the total decays. Now a experiment Freidrich et al has procued the first limit on an sterile neutrinos from beta decay to an electron. In experiments, Beryllium 7 decays to lithium 7, a positron and a neutrino are messured. The recoil of the lithium is measured. They exclude the mass range 100 - 850 keV for a faction of 0.01% (1 part in 10000) neutrinos being heavy. Of course a great deal of the mass range is still allowed, included the 7keV right handed neutrinos, that might explain the 3.5 keV galactic center x-ray spectra. Another paper from last here, Daya Bay and Minos looks and oscillation from standard neutrinos to other states, and excluded the Miniboone and LSND missing neutrino results at 99% confidence level. However axial force theory does not predict neutrino oscillation between the left and right handed states, instead it predicts the the right handed neutrinos produced above decay, leading to a small reduction of neutrinos in the near detectors, and slight more in far detectors, as the RH neutrinos decay back to LH ones. The paper does published the raw detector measurements, only the processed dates. But since the force constant of the axial force is small, (maybe an eightyth or hundredeth of the electromagnetic force), this probably would not be detected. This summer Microboone at Fermilab is scheduled to present further measurements that may detect or exclude some parameter space for right handed neutrino states, so we looking forward to reading the results.

Found an of interesting paper.

Verdini et al have a preprint on explaining the MiniBoone excess, (more than predicted electron neutrinos), by a decaying Mev Range right handed neutrino. They have the decay by photons coupling to the neutrino electric dipole. I think the much faster neutrino decay by a possible axial force, would arrive at a similar fit. They predict the neutrino state to be 376MeV and disappointingly they think the FANL (I think this means this Summers Microboone results), has too short a baseline to detect the new state or the decay. Previously Denler et al fitted the MiniBoone excess with a 100eV to 1 KeV decay neutrino.

Axial force doesn't explain Muon G-2 (Anomalus Magnetic Moment)

In the axial force exist and interacts purely with quarks and neutrinos which is how we have currently be looking at, it cannot explain muon G-2 now widely reported to be 4.2 standard deviations away from the standard model prediction. Under our model, the leading contribution to the magnetic moment of the muon is due to the diagram below, which is the standard leading W contribution with an axial force photon connecting the muon neutrino and one of the W particles. Their are 3 active copies of this diagram, with permuting the axial force vertices between the W and neutrinos, and allowing for a vertice between the two Ws. Plus another 3, where the axial force loop goes back to the originating line.

With the weak force and no axial force, the one loop contribution is, Rosetti, Castro & Pestieau, is 3.889e-9.

While the experimental difference, is around 2.9e-9. But the axial force contribution, picks up a fractor of 6 times the axial force strength coupling strength square or 6*4 pi alpha_a * the Weak contribution. To account for the anomaly the axial force would have a have the strengh \alpha=1/32 some five times stronger than the electromagnetic force, we had expected the strengh to be some 1/60 as strong as the electromagnetic force. It is highly doubtful that such a strong axial force could have been missed. It should be noted that while a force on an electron is highly constrained, a electronophobic neutrinophilic interaction not so much, they would however be a force on quarks leading to invisible energy lost in Hadron Jets.

An Axial Force Engine.

If the axial force exists, and KeV right handed neutrino swarm around heavy neuclei, to cancel out the axial charge. Then an Engine releasing heat engine, is possible. The main material used would be a salt of heavy elements, e.g. Barium Iodide, that releases heat on mixing with water. In Axial Force Theory part of the heat comes from the fact that heavy right handed neutrinos, HRHN, surround the heavy element, while anti-HRHN surround the hydrogen in water. On solution, the anti and regular neutrinos annhilate release axi-photons that a absorbed by other neucli and become heat energy. The solvated water and salt, can then be allowed to dry out, during drying background neutrinos are absorbed into water and anti-neutrinos into the salt. The process may then repeat. Thus an engine formed, that creates heat energy from background cosmic neutrinos.

MiniBoone experiment finds 4.7 Sigma Excess of electron neutrions where muon neutrino expected

This papger, explains it by the decay of around 100MeV right handed neutrinos to a left handed electron neutrinos via a axion like particle (spin 0 Boson), MiniBoone Excess Paper more detail to come

Found paper on Explaining Reactor 5 MeV neutrino excess with axial or vector neutrino interaction

Experiments measuring neutrino fluxes from nuclear reactors have found an excess of neutrinos at 5 MeV. effrey M. Berryman, Vedran Brdar, and Patrick Huber wrote a paper arXiv:1803.08506. That seeks to explain this by neutrinos ejecting neutrons from carbon-13 via an new interaction, either vector or axial. They actually found a good fit, but then rule it out by the lack of deutrium photodistintegration from neutrinos. Without a full calculation, we suggest, that given a charge assignment of plus a half on protons and minus a half on neutrinos, deutrium will be overall neutral to the new force, and only weakly interact via dipole moment, carbon-13 however a an uncancelled neutron that can full interact with the new force. Such a charge assignment is one we made for the axial force in 2009.

Found paper that shows Miniboone electron neutrino excess can be well fitted by a sterlie neutrino decaying to electron neutrino

The paper arvix:1911.01427 Finds a good fit for a forth sterile 1eV-100Kev neutrino decaying to electron neutrinos and a light boson, in the same mass range. This fits with my 2009 paper where there are right handed neutrinos decay to anti-left handed ones and a axiphoton.