Peter, also Peter, you comment that molecules would be ripped apart by black holes.
That is a likely conclusion, however, there is another scenario that does involve complex RNA-DNA mapping coming from black holes, or some other compressive celestial body, that does not involve molecules. Fuller predicted the transmission / teleportation of humans around the Earth via some Electro-magnetic-like phenomena by 1985. This teleportation of matter via EM-like phenomena would be natural next presumtion a line with human activities involving transmission of sound, and images via EM radiation. If matter can be taken apart, and mapped --seeFullers proposals in Synergetics-- and transmitted via some EM-like radiation, then it *may* also be possible, that, the mapping blueprints for human RNA- DNA is within a black hole cosmic egg, or some other compressive egg celestial phenomena, that sends out these coded mappings radiationally. When these radiations encounter the proper enviromental circumstances they might convert the radiation to matter, an more specifically, the most complex RNA-DNA if not also less complex RNA-DNA material. Rybo On Feb 10, 2009, at 7:56 AM, rybo6 wrote: > Peter, > > The article below makes clear, that, more complex peptide molecules > can be formed from less complex molecules, via compressive forces. > > The question(s) then becomes, at what level compressive force, would > we achieve the most complex molecules, without destroying the > molecules and what celestial phenomena? > > Rybo > > <http://www.pbs.org/wgbh/nova/transcripts/3112_origins.html> > > And just what happens to things like amino acids when they slam into > Earth with such devastating power? > > To answer those questions, one scientist came up with an ingenious > experiment. Using a huge gas-powered gun, Jennifer Blank simulates > the extreme pressures and temperatures that are unleashed when a > comet smashes into Earth. > > JENNIFER BLANK (Lawrence Livermore National Laboratory): We set out > to test whether or not materials would survive or whether they would > break down. And we expected that, or we were hoping that, some > fraction would survive. We figured the parts that didn't survive > would break down into smaller components, but in fact what we found > is much more exciting. > > NEIL deGRASSE TYSON: The gun fires a bullet at 5,000 miles an hour > towards a sample that represents the organic molecules inside a > comet. The sample consists of a solution of five different amino > acids, two of them present in every living cell. The mixture is > inserted into a steel capsule. The gun will send a shockwave through > the capsule simulating the extreme pressures of a comet's impact. > > JENNIFER BLANK: I think it's very hard to just imagine what kinds of > pressures we're generating in these experiments. If you think about > going to the bottom of the ocean, the pressures you'll have there are > only a hundred times atmosphere. So these are hundreds of thousands > of times atmospheric pressures. > > NEIL deGRASSE TYSON: Will Jennifer Blank's experiment show that the > building blocks of life can survive a crash landing on Earth? > > JENNIFER BLANK: Clear the room...Charging now...Okay, bringing up the > X-rays...35. Three, two, one, fire. Three, two, one, fire. > > NEIL deGRASSE TYSON: When they remove the capsule it's undamaged. But > have its contents survived the impact? > > The once clear solution of amino acids has turned a tarry brown > color. And the analysis revealed that not only had the material > withstood the colossal pressure of the impact, but it had transformed > into a new compound. > > Amino acids, combinations of carbon and other basic elements, had > fused together to form more complex molecules called peptides. > > JENNIFER BLANK: We went from our initial small compounds—and here's > an example of one of them, a simple amino acid—and we used the energy > associated with the impact to build larger molecules. Molecules like > this—this is a peptide—and we show that we can use the impact energy > to grow larger molecules from the simplest building blocks of life. > > NEIL deGRASSE TYSON: Peptides link together to form larger building > blocks, proteins, which make up all the cells in our bodies. But the > leap from non-living ingredients to a living creature, complete with > DNA which allows cells to replicate, is staggeringly complex. > > No one knows how this process started or what course it took. > > ANDY KNOLL: It is hard to really get your head around the great leap > from non-living to living. > > LISA PRATT: Well, it's hard enough that nobody's succeeded in doing > it in the laboratory. > > ------------------------------------ > > To post a message, send plain text only to: > [email protected], to send a message to the list owners send > to [email protected]. Patent searches at http:// > www.google.com/patents > Yahoo! Groups Links > > <*> To visit your group on the web, go to: > http://groups.yahoo.com/group/synergeo/ > > <*> Your email settings: > Individual Email | Traditional > > <*> To change settings online go to: > http://groups.yahoo.com/group/synergeo/join > (Yahoo! 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