If that Hydrogen exists in the voids as Inverted Rydberg Matter I am not so sure...
On Tue, Aug 21, 2012 at 10:19 AM, Jojo Jaro <[email protected]> wrote: > ** > I believe you are incorrect with this hypothesis. > > The walls of a metal crack or void are not solid. They are porous such > that a hydrogen ion can easily slip pass and diffuse in between the > inter-atomic gaps. I don't believe a collapse of the void will compress > the H+ ions in it enough for it to fuse. > > I believe this hypothesis of yours is similar in concept to cavitation > collapse fusion. Which I believe is generally considered "Hot fusion". > > What you need is an environment that screens the coulomb barrier repulsion > to allow these ions a chance to fuse. > > > Jojo > > > > > ----- Original Message ----- > *From:* ChemE Stewart <[email protected]> > *To:* [email protected] > *Sent:* Tuesday, August 21, 2012 9:49 PM > *Subject:* Re: [Vo]:Topology is Key. Carbon Nanostructures are King > > I agree with most of that although i expect carbon nanotubes to remain > rigid while heated. I think having a metallic lattice crack/void > completely filled inverted irydberg matter and then having that voild > collapse arond it when it thermally expands due to heating and electrical > stimulation is what triggers/ignites the magic. > > On Tuesday, August 21, 2012, Jojo Jaro wrote: > >> ** >> Let me ellucidate another reason why I believe in Carbon Nanohorns is the >> right NAE. >> >> Understand that a Carbon Nanohorn is essentially a long long pipe with an >> open end on one end. H2 in molecular form can diffuse into the carbon >> nanohorn or pass thru from the open end and accumulate inside the pipe. >> This is a known phenomena as CNTs have been investigated as possible >> hydrogen storage media for fuel cells and hydrogen cars. >> >> Now, imagine a long pipe and you pass a high voltage spark along this >> pipe. What would happen is you would ionize the H2 molecules inside this >> pipe by virtue of the high temps. Then you would have an environment with >> huge electrostatic potential and charge accumulation. An environment where >> the coulomb barrier is screened. So what will the H+ ions do? Invariably, >> they now have a strong tendency to fuse into He instead of chemically >> reacting back to H2. When H2 becomes H+, the H+ ions are especially >> confined inside the nanohorn due positive charge repulsion from the carbon >> atoms making up the Carbon nanohorn walls. Once H2 ionizes, it is >> essentially "trapped" inside the nanohorn wall cage. This, together with >> compression due to pressure, charge repulsion towards the center of the >> nanohorn, coulomb barrier screening due to charge accumulation and thermal >> collisions should increase H+ chances of fusing. >> >> This is the environment I am endeavoring to achieve and I believe it has >> great potential. >> >> >> Jojo >> >> >> >> ----- Original Message ----- >> *From:* Jojo Jaro >> *To:* [email protected] >> *Sent:* Tuesday, August 21, 2012 7:14 PM >> *Subject:* [Vo]:Topology is Key. Carbon Nanostructures are King >> >> Gang, There has been a lot of discussion about various LENR results >> lately. In these discussions, I think a consensus is building up that the >> key to successful LENR is topology. >> >> There has been flurry of discussions about ICCF papers that we keep on >> forgetting that ICCF results like Celani's are the old ways. Even if >> Celani perfects his technology, it would still be a far cry from beng >> commercializable. >> >> I say we take it a notch further. I say we moved from LENR (FP, Celani) >> to LENR+ (Rossi) to LENR2 (Carbon nanostructures). I say we move from Pd >> and Nickel lattice to a topology that can be easily engineered and >> created. With new capability to engineer a specific topology, we can >> create topologies of various sizes and experiment on them. >> >> I am talking about carbon nanotubes to be exact. Oxidized Carbon >> nanotubes (Carbon Nanohorns) to be specific. >> >> Let me elaborate. >> >> Recent studies indicate that vertically aligned CNTs can be created in a >> straightforward and repeatable process. The diameters of these CNTs can be >> adjusted by adjusting catalyst deposition rates (Hence particle size), >> catalyst kind and many other experimental conditions. SWNTs from 0.4 nm up >> to 100 nm MWNTs can be easily synthesized on various substrates like >> Nickel, steel and stainless steel. CNT heights up to 7 mm has been >> achieved. (That's right, 7 millimeters, not micrometers) The tops of such >> CNT forest can then be "chopped off" by high temperature oxidation in air >> or some mild acid. With that, we are left with a mat of CNTs with open >> tops of various sizes. These open Carbon nanohorns would have a variety of >> void sizes ranging from 0.4 nm to maybe 50 nm. With a plurarity of void >> sizes, one void ought to be the perfect size for LENR Such mats are ideal >> topologies to hunt for the size of the ideal NAE structure. >> >> We then pump an electrostatic field on the tips of these CNTs to allow >> for charge accumulation and field emission on the tips. The huge Charge >> accumulation would provide an environment where the Coulomb Barrier is >> screened. Any H+ ion who happens to drift by this huge charge environment >> would be greatly at risk of being fused with a similarly screened ion. The >> open voids of the Carbon nanohorns would further enhance such effects. >> This is of course the envronment we are aiming for based on our current >> understanding of how LENR proceeds. >> >> >> When we achieve LENR/Cold fusion on such a void, it would then be a >> matter of narrowing the search for the best void size to improve efficiency >> and output. And Carbon Nanohorns enable us to do this with known and >> repeatable processess to engineer these voids of specific sizes. Carbon >> nanohorns give us this unprecedented capability that metal lattice can not >> afford. Metal lattice cracks and voids can not be easily engineered and >> are quite susceptible to metal diffusion, metal migration, sintering and >> melting. This complicates the search. Carbon nanohorn voids are >> chemically and thermally stable lending itself to more repeatable >> experiments. And the nice thing about this, is that all the parameters are >> adjustable - such as void size, CNT height, electrostatic field strength, >> ion concentration via pressure adjustments, temps etc. Such environments >> affords us a good platform to hunt for the right voids. >> >> Axil contends that Ed Storms introduced this idea of topology as key, but >> I say, he also recognized the huge potential of Carbon Nanotubes as >> possible NAEs. >> >> I say we move past LENR and even LENR+ and concentrate on hunting for the >> right topology using Carbon Nanohorn mats. >> >> >> Jojo >> >> >> PS. In the spirit of scientific openness that gave us "gremlins" and >> "Chameleons", I dub this new idea of mine as the "Horny Theory of LENR" >> >> >> >
