https://arxiv.org/pdf/1010.1591
Influence of Relic Neutrinos on Beta Radioactivity The weak force scope of activity is considered to be exclusively located in its actions inside the nucleus of the atom or the subatomic particle. But the fact that the weak force is acting at a distance beyond those locations implies unambiguously that grand unification of forces are occurring during the "reaction". One instance of weak force action at a distance is the instantiation of isotopic changes in isotope stabilization caused by some cosmic mechanisms. The experiments by Alexander Parkhomov is a solid indicator that some new particle is producing weak force reactions at a distance. Parkhomov's experiments indicate that it is likely that the new unknown exotic weak force boson is generated by dark matter since the data shows cosmic influence associated with a pronounced variable nature of beta decay. Parkhomov is correct to attribute regular patterns in beta decay to cosmic factors, but the particle that he has selected to be the weak force carrier doesn't fit well to the data. I think a better fit is a dark photon that is expected to carry the long range weak force under grand unification. This photon could be the X-boson that is produced by dark matter. This weak force boson could be massless as expected but retain the nature of the photon with the exception the X-boson restricts its interaction with matter exclusively to the weak force. But it is possible that the X-boson could have a Higgs force linkage that generates some mass and sub-light seed behavior. Parkhomov has developed a weak force based isotopic telescope that generates data which shows gravitational focusing. effects of isotropic flux of weak force carrying particles. N.A. Kozyrev has also observed stars by means of an isotopic weak force telescope reflector showing similar gravitational lensing data patterns. Parkhomov points out the conformation of deviations from exponential decay rates. Any measurements of the rates of radioactive decays should reveal only an exponential decrease along with superimposed chaotic fluctuations obeying Poisson distribution. Lately however, after it became possible to conduct accurate long-term measurements, some experimental results, which appear to indicate the existence of periodic and sporadic deviations from the exponential law, were obtained. Also, the weak force data is sensitive to the use of a diffraction grating which indicates that the weak force carrier has a wave nature. It has been shown that the weak force can be amplified by the application of laser light onto gold nanoparticles. This speaks against the neutrino as the weak force carrier since there is no connection between photons produced by a laser and the production of neutrinos. It is likely possible to characterize the nature of the dark matter weak force carrier by using a time of flight experiment using laser excited nanoparticles to determine the speed of the weak force carrier, its mass if any, and the potential that it is carrying.