tag:blogger.com,1999:blog-326167780677397310.post1930851586726450266..comments2024-03-27T21:35:04.988-07:00Comments on EGO OUT: JUST A BIT MORE THAN LENR INFO FOR AUG. 13, 2015Georgina Popescuhttp://www.blogger.com/profile/04628821029016016988noreply@blogger.comBlogger10125tag:blogger.com,1999:blog-326167780677397310.post-4085568698154458992015-08-15T13:52:57.066-07:002015-08-15T13:52:57.066-07:00... continued
and on springer a huge bibliography...... continued<br /><br />and on springer a huge bibliography<br />http://link.springer.com/search?facet-creator=%22I.+P.+Chernov%22<br /><br />http://link.springer.com/article/10.1134/S1063776111050104<br />The yield of the products of nuclear reactions from deuterated palladium and titanium irradiated by an electron beam and X rays has been studied. Charged particles have been detected by CR-39 track detectors, which are not sensitive to electronic noise, electrons, and X-ray photons. To identify the type of particles and to estimate their energy, three detectors covered by aluminum and copper foils of various thicknesses have been used. It has been established with reliable statistics that 30-keV electrons and X rays initiate the synthesis of deuterons in the Pd/PdO:D x and Ti/TiO2:D x systems with the yield of 3-MeV protons.<br /><br />http://link.springer.com/article/10.1007/BF02509687<br />Changes in the isotopic composition of electrolyte lithium are studied experimentally when thin-film titanium-aluminum systems are enriched in hydrogen. Strong deviations of the lithium isotope concentration from their natural abundances are observed both in the surface titanium layer and at the titanium-aluminum interface. Analysis of the experimental results permits us to conclude that isotope-induced transformations occur in materials enriched in hydrogen due to cold diffusion of impurity atoms stimulated by hydrogen migration and non-equilibrium chemical reactions.<br /><br />http://link.springer.com/article/10.1007/BF02509681<br />We have studied changes in the isotopic composition of niobium and palladium as well as of titanium film structures over ceramics enriched in deuterium. We have also investigated changes in the isotopic composition of copper under thermally activated copper diffusion into nickel. An intense isotope exchange between the atoms of the matrices and impurities enriched in deuterium and changes in the isotopic composition of copper during diffusion into nickel were observed. The relationships seen in the experiments lead us to suggest that the changes in the isotope ratio may be caused (along with plausible nuclear transformations) by a strong isotopic effect involved in cold diffusion induced by hydrogen migration.<br /><br /><br /><br />wooh... that is work!<br />Alain_Cohttps://www.blogger.com/profile/08352476615242858677noreply@blogger.comtag:blogger.com,1999:blog-326167780677397310.post-71703790477672661392015-08-15T13:52:34.345-07:002015-08-15T13:52:34.345-07:00I found first
http://www.linknovate.com/publicatio...I found first<br />http://www.linknovate.com/publication/production-of-high-energy-deuterons-upon-electron-beam-excitation-of-deuterium-saturated-palladium-356834/<br /><br />"High-energy deuterons by electron-beam excitation of deuterium-saturated palladium were produced. The results show that atomic deuterium exhibits an extremely high mobility in metals, which is approximately 10-15 orders of magnitude higher than the mobility of heavy impurities at the same temperatures. The displacement of deuterium from localization sites becomes thermally nonequilibrium and is stimulated by the energy of long-lived nonequilibrium vibrational excitations in the hydrogen subsystem of crystal. The increase in the concentration of deuterons as centers of absorption and scattering of plasmon energy is accompanied by an increase in the deuteron energy. When the surface of palladium saturated with deuterium and hydrogen is oxidized, no transition of deuterium and hydrogen to unsaturated palladium is observed either in the absence of current or during the passage of current of any directivity via PdD-Pd contact."<br />http://link.springer.com/article/10.1134%2FS0018151X1004019X?LI=true#page-1<br /><br />and matching conference proceeding<br />http://www.linknovate.com/publication/charged-particle-emission-during-electron-beam-excitation-of-deuterium-subsystem-in-pd-and-ti-deuteride-targets-1299931/<br />"Energetic charged particle emissions accompanying deuterium desorption from specially prepared Pd/PdO:Dx and TiDx targets in vacuum, stimulated by electron beam (J ~ 0.6 mA/cm2, U = 30 keV) have been studied using a set of CR-39 plastic track detectors covered with various metal foil filters. It was found that the electron bombardment of those targets is caused by statistically significant emissions of DD-reaction product (3 MeV protons), as well as high energy alpha particles (11-20 MeV). At the same time the Pd/PdO:Dx and the TiDx samples show no sign of nuclear emissions during vacuum exposure without e-beam stimulation. Extrapolation of both the DD-reaction cross section and the enhancement factor (consistent with calculated screening potential Ue = 750 eV) to very low deuteron energy allowed us to satisfactorily describe the detected DD-reaction yield in Pd/PdO:Dx target, assuming "hot" deuteron (Ed ~ 3.0 eV) generation under e-beam bombardment. This result strongly supports the theoretical prediction [1,2] with regards to electron excitation of the D- subsystem in Pd- deuterides."<br />(ICCF14)<br />...<br />to be continuedAlain_Cohttps://www.blogger.com/profile/08352476615242858677noreply@blogger.comtag:blogger.com,1999:blog-326167780677397310.post-42645889182553459582015-08-14T03:27:20.950-07:002015-08-14T03:27:20.950-07:00Yes, it is. I wrote about the school, Univ of Toms...Yes, it is. I wrote about the school, Univ of Tomsk here:<br />http://egooutpeters.blogspot.ro/2015/05/the-spirit-of-znanie-sila-and-its.html<br /><br />you are a good websearcher, even excellent in such cases<br />search on Ego Out for the first author i.p. chernov or "ego out" "i.p. chernov" You can find info at the Univ Tomsk.<br />tell me please if it is OK.<br /><br />Peter<br />Anonymousnoreply@blogger.comtag:blogger.com,1999:blog-326167780677397310.post-62491356656887294662015-08-14T02:58:23.620-07:002015-08-14T02:58:23.620-07:00Hi Peter,
on cobraf I fall on that russian article...Hi Peter,<br />on cobraf I fall on that russian article that google cannot stranslate at all<br />http://www.lib.tpu.ru/fulltext/v/Bulletin_TPU/2000/v303/i3/06.pdf<br /><br />is it interesting for LENR ?Alain_Cohttps://www.blogger.com/profile/08352476615242858677noreply@blogger.comtag:blogger.com,1999:blog-326167780677397310.post-58640179032066987192015-08-13T19:29:19.367-07:002015-08-13T19:29:19.367-07:00Why do muons take so long to decay when produced b...Why do muons take so long to decay when produced by Rydberg matter?<br /><br />The muon decays when a W- appears from the vacuum. This appearance is timed by the probability of the decay of the muon. But if the vacuum is energized so that it has an excess of positive vacuum energy. then the W- will not appear on time, the muon will be delayed as it usually does. Excess vacuum energy slows down time. A excess of positive vacuum energy appears if a corresponding zone of negative vacuum energy is present. <br /><br />The delayed decay time of muons allows the to catalyze far more fusion events because they are are around for so long. <br /><br />That zone of negative vacuum energy exists inside the SPP. Negative vacuum energy speeds up time a lot. This acceleration of time is why radioactive isotopes produced by fusion in LENR decay almost instantaneously. That is because the ash from a fusion event is entangled with the inside of the SPP in which all the energy of the fusion event is delivered through teleportation.<br /><br />See this reference about vacuum energy<br /><br />http://www.bibliotecapleyades.net/ciencia/negativeenergy/negativeenergy.htmAxilhttps://www.blogger.com/profile/07190120527431077518noreply@blogger.comtag:blogger.com,1999:blog-326167780677397310.post-85922496817106307732015-08-13T11:59:14.321-07:002015-08-13T11:59:14.321-07:00Dear Ecco,
I do not know who you are, but I think...Dear Ecco,<br /><br />I do not know who you are, but I think you make too far bisociations.<br />What Leif is doing is wonderful, Defkalion has used Rydberg matter, but are you sure it is present as such in the Hottest Cats?<br />For me this is too bold thinking. mixing things that are too far. I do not say that you are in error but say you have not read the Svenn papers= what explanations could you find then?<br />Systems are too different, for me.Ultra dense hydrogen at 1350 C...?<br />In alumina or something similar. Non mi piace<br />PeterAnonymousnoreply@blogger.comtag:blogger.com,1999:blog-326167780677397310.post-75505073556568022302015-08-13T09:58:52.597-07:002015-08-13T09:58:52.597-07:00Peter: Leif Holmlid's research on Rydberg matt...Peter: Leif Holmlid's research on Rydberg matter suggests that long-lived Rydberg states of hydrogen can form upon desorption of hydrogen atoms from metal oxide surfaces, especially comprising alkali metals (which is typical of certain catalysts). Under the proper conditions, these excited Rydberg hydrogen atoms can condense into clusters that can further de-excite into what Holmdlid et al. call ultra-dense hydrogen, whose density is such that it can easily engage in more or less standard nuclear reactions (typically through Coulomb explosion or high voltage discharge). You might have read a few papers about this subject lately by Holmlid and Ólafsson.<br /><br />I'm tentatively proposing that the anomalous reaction is indirectly occurring in the walls of the ceramic tube or the oxide layer of the heating wire (if the ceramic tube is porous to hydrogen ions) through ultra-dense hydrogen production, and that catalytic processes are involved with this.Anonymousnoreply@blogger.comtag:blogger.com,1999:blog-326167780677397310.post-54615943272468255792015-08-13T09:09:10.091-07:002015-08-13T09:09:10.091-07:00Dear Ecco,
thanks for the ideas. What reactions c...Dear Ecco,<br /><br />thanks for the ideas. What reactions can take place in the cearmic tube, what do you suggest? The interface is also interesting.<br />For the heating wires- the standrd Achiless Heel of the reactor I have suggested month ago to eliminate them and work wireless- with the ceramic reactor body immersed in molten metal (eternal) as tin uused for flat glass manufacture a la Pilkington, but nobody has tried it till now and it is a pity.<br />Best,<br />peter<br />PeterAnonymousnoreply@blogger.comtag:blogger.com,1999:blog-326167780677397310.post-5658233998333926472015-08-13T09:09:04.318-07:002015-08-13T09:09:04.318-07:00Dear Ecco,
thanks for the ideas. What reactions c...Dear Ecco,<br /><br />thanks for the ideas. What reactions can take place in the cearmic tube, what do you suggest? The interface is also interesting.<br />For the heating wires- the standrd Achiless Heel of the reactor I have suggested month ago to eliminate them and work wireless- with the ceramic reactor body immersed in molten metal (eternal) as tin uused for flat glass manufacture a la Pilkington, but nobody has tried it till now and it is a pity.<br />Best,<br />peter<br />PeterAnonymousnoreply@blogger.comtag:blogger.com,1999:blog-326167780677397310.post-81538515967262564292015-08-13T08:57:14.965-07:002015-08-13T08:57:14.965-07:00A possible explanation could be that the reaction ...A possible explanation could be that the reaction is occurring in the ceramic tube or at the interface between the tube and the molten nickel (or the heating wire, even).Anonymousnoreply@blogger.com