Now, let us consider what makes Hydrogen Rydberg matter special in LENR engineering.
One cause for the special nature of the hydrogen Rydberg matter nanoparticle is its potential to focus SPP radiation from the tip of the hydrogen Rydberg matter particle. The plains of the Rydberg matter particle could accumulate, transfer through parabolic reflection, and focus the SPP magnetic beams that are generated along the entire length of the Rydberg molecule into a tightly focused spot in front of the nanoparticle. <http://imagebank.osa.org/getImage.xqy?img=QC5sYXJnZSxvZS0xNS0xMS02NTc2LWcwMDI> On Thu, Nov 12, 2015 at 2:38 PM, Axil Axil <janap...@gmail.com> wrote: > Rydberg matter is a nanowire. This is a nanoparticle. The shape of Rydberg > matter is important. It acts as an antenna that transmits magnetic power > with each flack of the nanowire sending magnetic power to the tip of the > particle. If there are 10,000 levels, then these 10,000 flacks produce > magnetic power sent to the nanowire tip. This mechanism is an EMF > amplification mechanism. This mechanism has been experimentally verified > and I have shown fluorescent micrograph pictures of this process here > multiple times. > > On Thu, Nov 12, 2015 at 11:09 AM, Bob Higgins <rj.bob.higg...@gmail.com> > wrote: > >> Jones, your description below about metallic hydrogen stimulates me to >> wonder about atoms, molecules, particles, and condensed matter. Obviously >> a single atom of H is not metallic hydrogen. A single molecule of hydrogen >> is more "dense" than the H/D(1) species of Rydberg matter. I don't think >> anyone would categorize an ordinary H2 molecule as metallic or condensed >> matter. The X(1) species of Rydberg matter is shown to exist in particular >> for H/D and the alkali metals having commonly 7 or more atoms. Are these >> Rydberg clusters better described as large molecules? A small particle of >> metal? Generalized condensed matter? How do you ascribe mass density to >> something only one atomic layer thick? It is interesting to consider. >> >> The Rydberg matter "snowflakes" called X(1), where X is usually an alkali >> metal, are called Rydberg because the electron orbitals are highly excited >> Rydberg states in high order flattened (nearly planar) orbitals. The >> nuclear separation of H(1) is bigger than that for the H2 molecule. >> Existence for X(1) Rydberg matter particles (clusters, molecules) is well >> reproduced, modeled, measured, and is utilized by many based on the well >> described characteristics of the snowflakes obtained, in a large part, from >> rotational spectroscopy. >> >> The existence of Holmlid's ultra-dense form is not reproduced, and what >> form it might take is completely speculative. The evidence for it appears >> to be solely from the accelerated species found in supposed Coulomb >> Explosion (CE). Why is this species not be examined by conventional >> rotational spectroscopy, as has been used to verify the existence of the >> X(1) Rydberg matter? I would think that the comprising atoms could NOT be >> in a DDL state, because if they were, they would not be susceptible to >> photonic ionization (DDL states are supposed to have too little angular >> momentum to form a photon), which Holmlid claims causes CE and is his basis >> for the existence of the D(-1) / D(0) state of matter in the first place. >> Since the D(-1)=D(0) matter is supposedly susceptible to photo-ionization >> and CE, it seems like it should also be detectable in a rotational spectrum. >> >> On Thu, Nov 12, 2015 at 7:25 AM, Jones Beene <jone...@pacbell.net> wrote: >> >>> Fran - The only way Holmlid’s claims make sense is that the dense >>> hydrogen he describes is a more stable phase of hydrogen than metallic >>> hydrogen. This means it is a phase or isomer which does not require extreme >>> containment. >>> >>> >>> >>> For instance, we know that alloys with alkali metals will lower the >>> pressure requirements for metallic hydrogen by 400%. In the case of the >>> Holmlid phase, which I still call DDL until it is shown to be different, >>> the species could be stable without any pressure or with slight containment. >>> >> >
