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NEWSCIENCENEWSCIENCENEWSCIENCE physical structure has these fluid-form interaction features. The most complex has the same features regardless of the complicated detail. their prime material was located (see figure 11). Note: see D'Arcy Thompson's On Growth and Form (Cambridge University Press, 1917) on conformal equivalents. dark matter's footprint with sophisticated gravity lensing. The same results predict envelope enclosure surrounding galaxies. Our model requires just such a strong asym- metric enclosure. A galaxy worth of con- served informational mass will help balance the missing-mass ledger. \. Prime Location Elements of the Model Laminar flow rarely stays stable for long. Velocity and pressures will vary. The asso- ciated surface can deform or change aspect to velocity. Often the main contributor to laminar breakdown is the amplified messen- ger eigenfrequency. The more and stronger the frequency waves absorbed, the quicker the boundary layer velocity fluctuations trip the laminar flow to turbulent flow. We can say that laminar fluid-form inter- actions are nature's method for storage and retrieval of informational mass. Let's break it down into elements: * Informational waves absorbed into boundary layer. * Boundary carried as velocity fluctua- tions to naked singularity location. * Stops briefly, allowing time-locked polarity matching. * Transitions to negative space as infor- mational mass at rest potential state. * Reverses process for informational mass retrieval. * Boundary breaks up, releasing discrete informational frequencies into flow medium. ¢ Wormhole Events This covers our model pretty well, except for transitions from one host location to another and the history of transitions. We wouldn't mind skipping wormhole events and their sum of histories; the metaphysical baggage is a load. It is, however, a clearly predicted element of our model. Let's pass the Hollywood wormhole illustration and stick to the elements. Here are the transition elements: ¢ Shifts of informational mass from one host location to another are wormhole ¢ Neuroscience Neuroscience has tracked nerve impulse traffic to specific and localised function. It defines time-locked binding as memory images stored, then retrieved intact years or decades later. This is a crucial element in our model's predictions. Neuroscience is right in that nerve impulse traffic stores short-term memory in frequency space. Our model agrees that information is in frequen- cy waves until delivered by a boundary car- rier. It is informational mass only at rest potential state. events. ¢ Wormhole events are time locked. ¢ Naked singularities are interconnected by a time-locked history of wormhole events. Our model predicts a time-locked sum of histories interconnecting everything forever. This conclusion assumes informational mass at rest potential as the transitional state. Our research indicates this is probably true. It further assumes a 100% success rate for wormhole events. This seems less likely. A conserved sum of histories is a definite maybe. ¢ Genetics The binding problem is the same here. Genetics research has unravelled the genetic code. Genes are one-dimensional and scat- tered in less than 2% of the DNA string. DNA and RNA use a chemical alphabet to spell out natural form. Our model suggests the gene is naked singularity core memory until retrieved in the DNA-RNA protein cycle. It is not clear that boundary carrier elements play a direct role in storage and retrieval of genetic information. We think a specialised mechanism is at play in the dou- ble helix environment. cS A - Polarity B - Phase-Couple Point C - Chord Height D - Informational Mass We can go on with this, but it is just tweaking the same process into different sit- uations. Let's review how our story points fit the model. Towards Applied Research Our basic research is substantially com- plete. C. E. K. Mees, former director of Eastman Kodak Laboratories, defined basic research as "the examination of materials and phenomena to discover fundamental properties, relationships and trends". Mees went on to define applied research as "basic research combined with existing technology to yield new technology". We are moving on to applied research and we urge the reader to do the same. It has become evident that numerous applied research applications will be productive. The trick is to take what you know, insert the appropriate model elements and see what clicks. eo A - Polarity B - Phase-Couple Point C - Chord Height D - Informational Mass ¢ Physics We have decades-old calculations in front of us as we write. Richard Wayte, of the Imperial College, London, describes gravity in terms of mass loss transfer. This idea uniquely fits our model and has dramatic implications. It was refused consideration for lack of a suitable messenger particle function to consummate the transfer. High-energy physics needs to lose the preconceived notion of messenger particle function and broaden its approach to delivery mechanisms. Astrophysics is doing better. It has found ¢ Hermetic Science With modern tools in hand, it is easy to disregard the old hermetic scientists, but they were right about the gnomic geometry. Natural morphology does reduce to two- dimensional spiral-based planes and associ- ated enclosures. They knew exactly where Editor's Note: Henry Hallmon and Carl Hollingsworth collab- orated on Naked Singularity Geometry in 2001. They can be contacted c/- Gaspin' Air Graphics, PO Box 605, DeLand, Florida, 32721-0605, USA, tel (386) 985 5695, email hhallmon@aol.com. NEXUS ¢ 51 OCTOBER — NOVEMBER 2002 www.nexusmagazine.com