Update. Working on a rewrite of my paper since the Chrismas holidays, got family commitments and now learning React.JS for work, so i'm slowed down. It may be a year beforre i'm ready with it. In my last Post, i recanted on Fermi energy from neutrinos in ordinary matter. But i'm now going back to it. Nucleons have been measured to spin flip, and if this is possible, axial force charges conservation requires them to have the same charge for left and right handed particles, this means there are additionally heavy Tera-quark states with the opposite axial charge (Tera quark come from Seldon Glashows, https://arxiv.org/abs/hep-ph/0504287, paper from 2005. Looking into the amount of Fermi energy present, I looked at the energy of solution of halides, and assumed its all released. A 30keV Sterile neutrino state, would match the complete energy release from Lithium Chloride, while at would take a 600keV neutrino to match the energy from Lithium Iodide, however additionally the mass energy of the sterile neutrinos might be released making the energy comparsion harder. The energy released however may not be measureable its released to the neutrino sea in matter and which has very little thermal transfer to photon, via collusions with nucleii, the heavier the nucleii, and the more balanced the proton to neutron ratio, the least transfer of energy, as applies to any collusion of objects with unequal mass. It is noted that cold fusion (Now Low energy nuclear reaction) research did claim energy release from hydrogen atoms being absorbed into matter, axial fermi neutrinos could explain this, but would not explain it from deuterium. I've have also been looking my neutrino wavefunction again, and begin to turn to Dirac neutrinos, meaning right handed states, as well as heavier states, the KeV states were also a dark matter candidate if stable, via Lepton number conservation. The Dirac equal mass states would be harder to reconcile with big bang nucleosythesis. Recent limit neutrino number (the axiphoton would be unstable in dense matter due to plasma screening), from https://arxiv.org/abs/astro-ph/0202486, put a limit of 4.2 on the number of extra neutrino states. All three Dirac right handed states, plus a single KeV neutrino of each handness, comes to 5 states, in only a little tension with the limit. It seems the Muon magnetic moment, is now in 3 sigma tension with the standard model, indicating new forces or particles, https://arxiv.org/abs/2002.04822 However my axial forces loops in lepton magnetic moment Feynman diagrams are suppressed by a factor of the strength of the axial force, while the magnetic moment difference between the standard model prediction is about the size of the Weak force contribution. The axial force contribution is a thousand times (or more) to small to explain the descrepancy. At the muon magnetic moment doesn't rule out an axial force. Fridays paper on limit of new neutrino interactions from the COHERENT experiment, look at U(1) e-mu, mu-tau, and similar forces. The limits on the force strength at low mass Z prime are g<10^-4. If the Axial force detection amount is similar it is close to beginning to limit my renormalisation estimate of alpha_axial = 1/137 * 1/60, a sixtith of the strengh of the electromagnetic force.