Rydberg matter and the leptonic monopol This post is third in the series on Rydberg matter which includes as follows:
Cold Fusion Magic Dust Rydberg matter and cavitation IMHO, Leonid Urutskoev et al misinterprets the action of Rydberg matter as the leptonic monopole as proposed by Georges Lochak. Reference. http://www.lenr-canr.org/acrobat/LochakGlowenergyn.pdf Low-energy nuclear reactions and the leptonic monopole In this study of electric explosion of titanium foil in water, this group observed transformation of Ti48 into many transmuted elements. Similar to the LeClair experiment, a cavitation like reaction produces an electrically sensitive agent that shuts down the coulomb barrier. IMO, that agent is Rydberg matter. Included in this reference, experimental pictures of the path of this agent behave like boll lighting. The agent persists for long time, travels a long distance, and creates a distinctive trace pattern unlike an ion. Quoted from the reference. To make sure that the traces are not related to some electromagnetic artifact, we installed detectors near the foil remnants only after the explosion. During 24 hours we were registering the traces which were indistinguishable from those, observed at the instant of electric pulse. Thus, we have confirmed the nuclear origin of the radiation being registered. It should be noted that when the unit was subjected to a magnetic field [1], the traces in the nuclear emulsion changed. This is seen in the Figure 9. My Note: Rydberg matter will behave this way being long lived and electromagnetically sensitive. Doctor Ivoilov will present in his report some very interesting results for the traces [8]. Here are some conclusions based on the presented experimental data. 1. The particle which left the trace in the nuclear emulsion is charged, as nuclear emulsions are insensitive to neutrons. 2. The particle cannot have electric charge, as otherwise it could not be able to pass through two meters of atmospheric air and two layers of black paper. My Note: Rydberg matter(aka ball lightning) will behave this way. 3. The particle does not have high energy, as no delta-electrons are observed. 4. The mechanism of the interaction between the particle and the photosensitive layer is not clear. Assuming the Coulomb mechanism, the absorbed energy estimated using the darkening area equals around 1 GeV. 5. The radiation is of nuclear origin; it interacts with magnetic fields. My Note: Rydberg matter will behave this way being long lived and electromagnetically sensitive. I found this informative in the reference: A rather interesting question is whether Ti is the only element to possess this remarkable feature. The answer is no. Experiments with other types of foils (Pb, Zr, Ta and so on) were carried out, and isotope shifts were again detected. For example, the 208Pb isotope is the parent atom for Pb. It is noteworthy that the tendency for transformation is usually found for even-even nuclei. Note that this is only an observation rather than a statement. We did not carry out systematic studies with other foils, but we concentrated mainly on Ti. Note that to attain significant effects in these experiments, it is necessary to carefully select the current, the weight of the load, and other parameters for each type of foil. Nevertheless, the data obtained are sufficient to claim that each chemical element is transformed to give its own spectrum of chemical elements. The question of the isotope ratios of the chemical elements formed upon the transformation also cannot be passed over in silence. For the vast majority of chemical elements, we did not notice significant distortions of the isotope composition with respect to the natural distribution. This offers hope that we have not invented or imagined anything but only came across a natural phenomenon. Remember that Ni62 and Ni64 are Rossi preferred isotopes; these nickel isotopes have even-even nuclei. In closing, this reference is correct to point out that U235 can be enriched in a cheap and easy way using Rydberg matter. U238 which has an even-even nucleus will be easily depleted leaving U235 as residue. This may tempt the DOD to blackout cold fusion as a proliferation risk.
