RE: [Vo]:Motion Characteristics of Single Electrons of Atoms of Atomic Gas of HydrogenJones--
I think you are correct about Li. I had the same idea in reading the item. There is another interesting paper regarding electronic spin transitions in “hydrogen like” atoms at: http://www.scirp.org/journal/PaperInformation.aspx?PaperID=6677#.VZbBg0blxs4 The authors remark: “We first derive the spin dependent eigenstates of the hydrogen-like atoms then find a more accurate correspondence between these eigenstates. So far in literature the states have been denoted by the quantum numbers (n, l, j) [1] but not by the quantum numbers (n, l, mj). In this way, we distinguish the states in the Zeeman sense including the quantum number, mj. By using the Fermi-Golden rule, we calculate the non-zero matrix elements and then develop the spin dependent selection rules for the photonic transitions in the hydrogen-like atoms. ” I plan to email them and ask whether they can calculate coupling between the Li 7 nucleus and its atomic electrons as to allowed spin transitions and spin mass changes in the nucleus—i.e., the transition to Be-8 with addition of a H and on to its decay of two alphas. Bob Cook From: Jones Beene Sent: Friday, July 03, 2015 7:12 AM To: [email protected] Subject: RE: [Vo]:Motion Characteristics of Single Electrons of Atoms of Atomic Gas of Hydrogen This is interesting and it took a while to figure out what could be going on. You have to read between the lines (and even then, we need lots of clarification). In the context of the Hot-Cat - a “hydrogen-like atom” or ion is a heavier nucleus with one electron, and thus is isoelectronic with hydrogen (in terms of the emission line, especially the Balmer alpha line). The prime example of a hydrogen-like ion for the Hot-Cat, which in fact is the only one which is feasible for LENR is lithium – which is the Li2+ ion. Because this hydrogen-like ion is a two-particle system with an interaction depending on the distance between the two particles, the (non-relativistic) Schrödinger equation can be solved in analytic form, as can the (relativistic) Dirac equation with a spiral orbit and slight continuous IR emission. Here is specific info on the emission: https://en.wikipedia.org/wiki/H-alpha In short, because of a the calculated mathematics of this ions orbital, the electron could be a continuous emitter of IR radiation during the time the atom is ionized (which means it is inherently gainful if the ionization is protracted). The calculated cyclic frequency of the electron around the nucleus at the famous 656 nm alpha line is off by a slight amount, due to the extra charge of the nucleus which could imply that this emission line is being “resupplied” or pumped with energy from the zero point field on a continuous basis. This is my interpretation and obviously, I am reading a lot into the paper which isn’t there, so hopefully the author will explain it better (or else Puthoff will). If my interpretation is correct, the extra energy will be seen in the infrared with a strong signature. Jack Cole wrote: Dear Peter, He claimed this in an email to me regarding the paper. Jack Peter Gluck wrote: Dear Jack, where exactly does he claim that this is soemthing connected to LENR, E-Cat? In the paper? Cannot find it. Thanks, Peter Jack Cole wrote: This paper is a little beyond my knowledge base, but perhaps others can make more sense of it. Motion Characteristics of Single Electrons of Atoms of Atomic Gas of Hydrogen and Single Electrons of Hydrogen-Like Ions in Form Gas or Vapour during Decays of Such Atoms and Ions. Emission Line Spectra http://www.scirp.org/journal/PaperInformation.aspx?PaperID=49252#.VZZeXPlVhBe The author claims this may be an explanation for energy production in the E-cat. Jack -- Dr. Peter Gluck Cluj, Romania http://egooutpeters.blogspot.com -- Dr. Peter Gluck Cluj, Romania http://egooutpeters.blogspot.com
