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Roswell crash examined on 20 July 1996 at the Carnegie Institute at Sandia National Laboratory in Albuquerque, New Mexico, to in Washington, DC. A sophisticated ion microprobe instrument exotic metals manufacturers and other university specialists—has was used which could analyse magnesium isotopes. any knowledge of layering these metals in alternating layers in It was the third confirmation that there were only three ele- which bismuth is about one to four microns thick and magne- ments in the skin: bismuth, zinc and a bit more of the isotope sium/zinc is about 100 to 200 microns thick. **Mg than in the control sample of magnesium, but not outside normal terrestrial ranges for normal magnesium metals. The most | ANTI-GRAVITY CHARACTERISTICS OF METAL "SKIN"? striking anomaly was that the bismuth/magnesium layered materi- Speculation about what this layered metal material might do has al emitted 60 times more positive ions than the pure magnesium included resisting or detecting magnetic fields, because bismuth metal being used for standard comparison (see Plate 3). Ion has the greatest Hall effect and is the most diamagnetic of any microprobe analyst Erik Hauri wrote in his formal report: metal. Concerning the Hall effect, if a voltage is placed on bis- The Bi-Mg sample gave count rates of Mg+ ions which muth while the metal is in a magnetic field, a current flow will be were enhanced sixty times more than [the Mg+ ion count] in induced that is 90 degrees to the voltage. Bismuth's diamagnet- the pure Mg metal standard [used for control]. ism does not allow magnetic field lines to penetrate it. Bismuth Hauri suggested three possible reasons for the difference. First, also absorbs infrared energy which could be converted to electric- he explained that the zinc might act as a catalyst for magnesium ity. One tantalising suggestion was that the bismuth/magnesium ionisation. Second, that catalytic process might be enhanced if material would provide anti-gravity lift when surrounded by a there were a distinctive arrangement in the Mg crystal structure strong electrostatic force combined with a radio frequency (RF) which related to how the material was originally constructed. signal, a "Class C" RF signal, though no specific frequency was Third, if oxygen were somewhere in the sample it could enhance given. Mg ionisation. However, Hauri acknowledged that none of the That last suggestion came from a man who claimed to have ion microprobe spectra showed any oxygen. worked at Edwards Air Force Base, California, and Area 51, By then I had reported on "Dreamland" that the unidentified Nellis AFB, Nevada, from 1973 to 1979, back-engineering tech- metal pieces sent to us from the anonymous South Carolina nology retrieved from the Soviet Union during the Cold War. The source appeared to be made up of thin layers of nearly pure bis- man claimed that, during that time, layered metal with bismuth muth which alternated with thicker layers of nearly pure magne- and magnesium had come into his lab as an "unknown" and left as sium mixed with a little zinc. On the air, I asked if anyone listen- an "unknown". He also claimed he later learnt that if the bis- ing had any information about the construction or function of such muth/magnesium metal were placed in a million-volt electrostatic a material. field provided by a van de Graaff generator with an additional I have also contacted more than 50 people in the scientific and _ radio frequency (RF) signal applied, the metal would turn into a industrial community to see if I could find anyone who had "lifting body". worked with bismuth and magnesium/zinc and knew what the Laser optical physicist Travis Taylor at the Redstone Arsenal in metals might do layered together in the alternating and varying Huntsville, Alabama, had previously contacted me, offering to micron thicknesses. But, to date, no one—ranging from the help with experimentation on the metal "skins". So I contacted Director of Material Sciences at Massachusetts Institute of him about doing the electrostatic and radio signal experiment. He Technology (MIT) in Cambridge, Massachusetts, to metallurgists agreed to try, so in September 1996 he was sent a small piece of the skin which had been cut by the universi- 0.150 ty professor from one of the bigger pieces se he had analysed in his laboratory. nar The first stage of the Travis Taylor exper- ass. . iment was at 500,000 volts without the oaasd added radio signal. To compare DC versus 0.144 AC electric current, he tried both an AC op OMS Tesla coil and a DC van de Graaff appara- 2 nie 8 poems see sees eee Bi-Mg METAL tus. A control piece of normal aluminum a o140 ofunnneetpeeenenweanas Average= was cut from a pop can to compare reac- z ost ------}-----g --------------------------- J 0.1405 0.0014 tions in the field. 0.38 Mg Standard Taylor's videotape of this first experiment oas Averages showed a dramatic movement by the bis- 0.1978 0.003 muth/magnesium layered material. It moved sideways with such energy that it lit- erally flipped off the plastic insulator cap that Taylor was using to separate the metal 0.133: 0,132. 0.131 01304 —r ————+ 1 The aluminum control piece did not move at pieces from the van de Graaff generator. 1 2 3 4 8 6 all. Analysis Number After I reported this test, other scientists around the US called to say the experiment Plate 3: lon microprobe analysis graph showing comparison of bismuth/magnesium skin needed to be more refined to control for average isotope range for *Mg isotope compared to a standard average for terrestrial ly electrostatic effects. s set about magnesium. There was more 2M isotope than normal, but not outside normal terrestrial | PUr’Y etecttostatic eects, so we set about magnesium ranges. lon Microprobe analysis by Erik Hauri, Carnegie Institute, | ‘© do another experiment at a million volts Washington, DC, 20 July 1996. with the RF signal added. This time Taylor used only a DC van de at Sandia National Laboratory in Albuquerque, New Mexico, to exotic metals manufacturers and other university specialists—has any knowledge of layering these metals in alternating layers in which bismuth is about one to four microns thick and magne- sium/zinc is about 100 to 200 microns thick. Analysis Number 76 * NEXUS AUGUST - SEPTEMBER 1997