(word processor parameters LM=8, RM=75, TM=2, BM=2) Taken from KeelyNet BBS (214) 324-3501 Sponsored by Vangard Sciences PO BOX 1031 Mesquite, TX 75150 There are ABSOLUTELY NO RESTRICTIONS on duplicating, publishing or distributing the files on KeelyNet except where noted! October 18, 1992 NEMES1.ASC -------------------------------------------------------------------- This file shared with KeelyNet courtesy of Cal Newman. -------------------------------------------------------------------- Article from Science and Mechanics January 1964 First Photos of the Atom! by David Legerman A revolutionary new scientific instrument has been invented that penetrates to the heart of matter, the atom, and photographs it in color! The incredible microscope is called the Nemescope, and it is the culmination of years of research by Dr. Elmer P. Nemes, a 44- year-old Hungarian-born physician presently living in Beverly Hills, Calif. Prior to the development of the Nemescope, the most powerful magnifying instrument known to science was the electron microscope. But this has several drawbacks, not the least of which is that it produces black-and-white or grey shadow photos with very little internal structure shown. The electron microscope has an effective magnification of about 60,000X which can be further magnified photographically. However, there is no penetration of the structure of the examined material; nothing can be seen inside the surface. The Nemescope, which uses a ray of much shorter length than the electron, possibly below even the neutron range, gives beautiful penetration and resolution of internal structure. The new microscope costs a fraction of the electron microscope and requires specimen preparation no more complicated than that required by a simple optical microscope. In addition to producing photographs of sub-atomic structure in color, the Nemescope can also project the image on a screen or reproduce it via television. The secret of the Nemescope begins with the theory that if you can cause radiation of any substance, it will emit an image that can be converted to light, magnified, and photographed in color corresponding to its spectrum characteristics. Any solid, liquid, or gas could be excited by radioactivity in this manner and would respond by emitting at its own resonant frequency an image in true color, form, and spectrum. Page 1 Working on this theory, Dr. Nemes constructed his first model, a tank-like case shielded with lead that was a maze of knobs, wires, pipes, and cables. At first all controls were hand-manipulated, but the Nemescope is now ready for electrically driven controls with motors that have recorded movement intervals of 1/75,000th of an inch. A full explanation of how this remarkable instrument works would take many pages (it includes more than 20 original patents) but here is a brief outline: 1. The first unit is a cold cathode lamp with multiple units separately charged. The filaments are preheated by an input of 18 volts amplified to 608 volts at the emitting end. This cathode gun acts as the primary source of illumination and bombarder of the specimen to be examined. 2. The second unit is a condenser under vacuum with molecular nitrogen injected. In the condenser circuit are placed two radium guns each yielding 5,400,000 electron volts. The condenser includes a coil which carries by interchangeable switch from 240 megacycles to 35,000 megacycles in magnitron arrangement which hits the specimen to agitate or excite the molecular structure. 3. The resulting stream of energy is converted into light in the front orthicon tube, actually consisting of two tubes which pick up resonant frequencies in the high ranges. After amplification, the imaging orthicon emits a picture on the screen in color corresponding to the nature of the substance under examination. Results obtained with the Nemescope have been no less than astounding. In 1955, working with patients in the hospitals of Mexico City, Dr. Nemes succeeded in making pictures of cells from the blood and urine of cancer patients which established a relationship between human cancer and a virus. In 1957, enzyme battery research started by Dr. Nemes resulted in another breakthrough when for the first time enzymes were resolved under a microscope. Through the Nemescope enzymes can be classified and identified. When we realize that enzymes are the chemical catalysts of living matter and that viruses share with bacteria the responsibility for most infectious diseases, a microscope that will enable man to study more closely these ultra-microscopic substances is indeed a boon to mankind. Another exciting discovery made by the Nemescope is in the field of metallurgy. Behavior of metallic alloys under bombardment by the Nemescope has indicated that the present makeup of widely used alloys must be revised and new techniques developed to insure more stable bonding elements. Where the electron microscope showed perfect molecular alignment, the Nemescope photos showed fault lines and distinct weaknesses among bonding elements. Metal failure of hull welds or pipe welds may have been the cause of the sinking of the "Thresher". It's obvious that a closer look at the behavior of metals in the atomic or molecular regions must be made. The Nemescope, with its great magnifying and resolving powers, Page 2 will probably furnish the answers to these questions, as well as the answers to how materials behave when exposed to vacuum, ions and electrons, and the electromagnetic radiation known to exist in outer space. Nemescope photos of the structure of the atomic nucleus are beautiful in their resolution. Perhaps the most surprising and exciting sight is how the atomic particles are connected by "force lines" or bands of energy. Nemescope photos of sub-atomic structure have an amazing similarity to Rutherford models of the atom--those three-dimensional models of vari-colored balls held together with pencil-thin rods. Leukemia particles and the common cold virus, when photographed by the Nemescope in full color, have a precision in structure that can, perhaps, be appreciated only by a research scientist or laboratory technician. -------------------------------------------------------------------- If you have comments or other information relating to such topics as this paper covers, please upload to KeelyNet or send to the Vangard Sciences address as listed on the first page. Thank you for your consideration, interest and support. Jerry W. Decker.........Ron Barker...........Chuck Henderson Vangard Sciences/KeelyNet -------------------------------------------------------------------- If we can be of service, you may contact Jerry at (214) 324-8741 or Ron at (214) 242-9346 -------------------------------------------------------------------- Page 3