Hi Bob, Much thanks for your interest in this post.
In order to answer your question properly, it’s going to take some time… so be patient. I will respond in a series of posts. Post #1 Bob Higgins asked: “Rydberg hydrogen has a very loosely bound electron”. Axil answers: Besides hydrogen, many other elements and even various chemical compounds can take the form of Rydberg matter. For example in the Rossi reactor, I now suspect that the ‘secret sauce’ that Rossi tells us catalyzes his reaction is cesium in the form of Rydberg matter. I say this because of the 400C internal operating temperature range that Rossi says his reactor operates at. If this internal operating temperature is actually 500C, then the reactor may be hot enough for his secret sauce to be potassium based Rydberg matter. Bob Higgins asked: “With such large orbitals as Rydberg electrons occupy, how can such a phenomenon be considered inside a nickel lattice?” Axil answers: This Rydberg matter never gets inside the lattice of the micro powder. This complex crystal can grow very large (1). It sits on the surface of the pile of micro-powder where under the influence of its strong dipole moment, coherent electrostatic radiation of just the right frequency lowers the coulomb barrier of the nickel nuclei. Because this is an electrostatically mediated reaction, only the surface of the nickel micro-grain is affected. The electromagnetic field cannot penetrate inside the nickel grain. But this field does penetrate deeply in and among the various grains of the pile of powder to generate a maximized reaction with every grain contributing. The electrostatic radiation of this dipole moment catalyzes the fusion reaction. In detail, this strong dipole moment lowers this coulomb barrier of the nuclei of the nickel just enough to allow a entangled proton cooper pair to tunnel inside the nickel nucleus, but not enough to allow the nickel atoms of the lattice to fuse. Micro powder allows for a large surface area relative to the total volume of nickel. More surface area allows for more cold fusion reaction. This is why the use of micro powder is a breakthrough in cold fusion technology. On page 7 of the reference, this aspect of the experiment is revealing: “In order to complete the story of transformation, we should consider this problem: where does the transformation take place, either throughout the whole space of the explosion chamber or only in the plasma channel? To answer this question, we carried out experiments with uranium salts (uranyl sulfate, UO2SO4) [3].” The answer that they found was as follows: throughout the whole space of the explosion chamber. This is to be expected because the coherent dipole moment of Rydberg matter is extremely strong and long ranged. It is like an electromagnetic laser beam that can exert its influence over a distance of centimeters. (1) LeClair said he saw the size of one of his crystals as large as a few centimeters. On Tue, Mar 20, 2012 at 9:56 AM, Bob Higgins <rj.bob.higg...@gmail.com>wrote: > Nice posts on the Rydberg effects, Axil. I like reading them. Please > continue posting them. But, I am confused. Could you can help me > understand these questions: > > Rydberg hydrogen has a very loosely bound electron. How would these > Rydberg electrons survive high temperature phonon collisions without the > atom becoming ionized and as a result breaking up the condensate? > > With such large orbitals as Rydberg electrons occupy, how can such a > phenomenon be considered inside a nickel lattice? The electron orbitals > would extend greater than the nickel lattice spacing. Other condensates > are possible, but why would you think these are Rydberg? While we know > that the LENR appears to happen at the surface, and it also appears to > require support from within the lattice (loading) - so it sounds like some > kind of condensate effect is needed within the lattice. > > In the NanoSpire case, it is not clear how the H-O-H-O- crystals that form > are Rydberg. What evidence supports this? They may be some kind of > condensate, but not necessarily Rydberg. > > The large dipole moments you describe would certainly make it easy for the > Rydberg atoms to couple to other atoms electronically and form a condensate > from that coupling. However, I don't see how that strong dipole provides > support for the charge evidence that you described from NanoSpire. Can you > explain that a little more? > > > *On Sun, Mar 18, 2012 at 11:03 PM, Axil Axil <janap...@gmail.com> wrote:* > > 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 >>> >>
