Fred Sparber has proposed a new elementary particle, *Electronium* for which he will win the Nobel prize if he is proven correct.
Pause...silence... a few coughs and chuckles... but yes, you looked back didn't you, and I didn't add a 'smiley' there because this is a serious hypothetical proposal, albeit with little direct proof thus far, and it is such a fundamentally important insight, that even though it first appeared on what the mainstream establishment may consider to be a backwater news group, vortex, it is of absolutely overwhelming potential importance to all of science... IF correct, of course.... Plus, it is elegant in that it explains almost *all* OU or "excess heat" experiments, not involving fusion. It also explains deuterium 'stripping' which is a nuclear reaction. It also explains R. Mills excess heat. If... in the coming months, one should see a flurry of articles appearing in mainstream journals or newsgroups, advocating the same particle under a different name without attribution to Fred, be sure to direct their attention here. This could be important, folks. And you heard it hear first. OTOH perhaps not... perhaps someone today may suggest a good reason why it could not happen. Directed experiments will take longer. That is the nature of hypothesis and the scientific method. Time will tell. Fortunately, both Fred and myself have pretty thick skin, so have at it... ELECTRONIUM Two electrons bound with one positron into a stable particle. Consider it as a heavy electron, but just light enough to have escaped detection heretofore (except possibly by R. Mills who has concocted a thoroughly bizarre, at first glance brilliant (but under scrutiny a totally cockamamie theory) of nearly a thousand pages to explain what I will try to summarize in one page - a new rare but stable fundamental particle. You may also see some evidence of it on older oscilloscopes (more on that later). Spin 1/2, Net Charge minus 1.6e-19 Coulombs Mass 2* Me = 1.82e-30 kg, Radius 4.235E-15 meters 1st proton orbit (27.2 ev) radius 2.645e-11 meters Velocity 2.186e6 meters/sec (c*alpha) 2nd proton orbit (108.8 ev) radius 1.322e-11 meters Velocity 4.373e6 meters/sec 2 (c*alpha) 3rd proton orbit (244.8 ev) radius 8.816e-12 meters Velocity 6.558e6 meters/sec 3 (c*alpha) These should be created in the sun whenever 1.02 Mev photons create positron-electron pairs and they combine with an electron under enormous pressure. The electron in a P-e-P ----> D + neutrino reaction will most likely be an Electronium particle in a stellar environment. They will also decay rapidly in a stellar environment, so the only ones that escape are those that get accelerated away PDQ. Over the millennia, these rare but stable particles will accumulate in less hostile environments, so that in a few billion years a substantial number - a few parts or tens per million might be evidenced in certain elements with negative electron affinity: i.e. electronium would replace one of the electrons in such atmospheric elements as oxygen, or perhaps even nitrogen. Eventually these would work their way into water where they might appear with the same or greater frequency as deuterium. Electronium formation ab initio: -------> -q <------- + q --------> - q net charge - q Net Spin 1/2 3 times 0.511Mev - .511 Mev = 1.02 Mev (1.632e-13 joule) rest mass divided between the three disks gives about 0.340 Mev mass per disk. Hence a mass of 1.632e-19/c^2 = 1.82e-30 kg A positron is stable; it won't decay. When a positron finds an electron (after slowing down), they end up orbiting each other as positronium (Ps) for a while before they annihilate in our three space. In other words, Ps is not stable in our three space, but neither or eta-quarks... from which ALL matter is made... yet both quarks and Ps are both quite stable when bound in triplicate (according to this hypothesis). It is true that under normal circumstances, a positronium is electrically neutral and would have no interest in bringing another electron in to make a threesome. That is why these would be formed in cosmic, or stellar events, esp the supernova. The positronium will be prohibited from annihilation by the high energy fields or high gravitational fields until a after it has formed the stable particle. These charged particles would be rarity particles in stars, but stable over billions of years on planets, as the binding energy is in the hundreds of keV. Stay tuned or the next installment which will explore *how* this particle explains most of the energy anomalies which are routinely explored on this forum. Jones
