The only UCAR I'm aware if is University Corporation for Atmospheric Research.
https://www2.ucar.edu/ -mark From: Brian Ahern [mailto:ahern_br...@msn.com] Sent: Tuesday, February 28, 2017 3:07 PM To: vortex-l@eskimo.com Subject: Re: [Vo]:DESCRIBING THE MANELAS Phenomenon Who is UCAR? _____ From: bobcook39...@gmail.com <bobcook39...@gmail.com> Sent: Tuesday, February 28, 2017 3:35 PM To: Axil Axil; vortex-l Subject: RE: [Vo]:DESCRIBING THE MANELAS Phenomenon bRIAN--- You may wantg to contact UCAR, who seems to have a good knowledge of magnetics regarding reverse engineering the Manelaes device. Trace elements may be an important ingredient which will be hard to detect without destructive examination. Gadolinium is used in MRI (nuclear magnetic resonance) machines. As AXIL poin ted out, Gd has strong electronic responses as well as nuclear magnetic responses. It may be that the Gd in a Ba fe lattice is able to help nuclear-electronic spin energy coupling in a variable B field. Keep in mind that reonances are probably required for a couple. Thus, the allof the nuclear species spin energy states could be involved in a couple. The electronic spin energy states also change with the instantaneous B field. The spin coupling theory AXIL IDNETIVIED a few comments back may be another key for designing a good reverse engineering scheme. Bob Ciook Sent from Mail <https://go.microsoft.com/fwlink/?LinkId=550986> for Windows 10 From: Axil Axil <mailto:janap...@gmail.com> Sent: Monday, February 27, 2017 8:04 PM To: vortex-l <mailto:vortex-l@eskimo.com> Subject: Re: [Vo]:DESCRIBING THE MANELAS Phenomenon The goal is to duplicate the Manelas or Sweet magnet in order to run tests on the replicant. Replication is marked by the creation of a liquid like mobile magnetic bubble with a boundary that is easily movable located at the center of the magnet. The assumption is that the preparation process is common between these two types of magnets: barium or strontium. The difference between these two systems is most likely in the nature of the activation signal. Fabricating this special magnetic configuration seems to take a accumulation of experience so either barium or strontium magnets will serve well for practicing proper techniques. Replication process Buy at least 1 ceramic magnet of the appropriate size and material https://www.amazon.com/Applied-Magnets-Ceramic-Magnet-Block/dp/B0012DPKX6/re f=sr_1_105?s=industrial <https://www.amazon.com/Applied-Magnets-Ceramic-Magnet-Block/dp/B0012DPKX6/r ef=sr_1_105?s=industrial&ie=UTF8&qid=1488242881&sr=1-105&keywords=ferrite+ma gnets> &ie=UTF8&qid=1488242881&sr=1-105&keywords=ferrite+magnets This magnet in all probability will be strontium. --------------------------------------------------------- Test to determine what type of magnet was delivered. If the surface of the magnet does not conduct electricity (continuity tester) then the magnet is barium, if the surface does conduct electricity then the magnet is strontium. --------------------------------- Prepare the magnet by pre-treating it with high voltage electrostatic tension. Place two conductive plates(copper) on each side of the billet. This will form a capacitor out of the billet with the magnet as the dielectric. Apply high voltage (20,000 volts or more) of electrostatic potential to the billet. Capacitive breakdown of the dielectric billet should occur. Increase the voltage until capacitive breakdown does occur. ---------------------------------- Using a capacitor bank able to store voltages up over 1000 volts and 1000 joules of energy and a coil of wire wrapped around a plastic cylinder 8 inches in diameter This video shows how to build the magnetic conditioner. https://www.youtube.com/watch?v=nFarS-liuBY I would add a shelf upon which the magnet can sit that is located in the middle of the coil where the magnetic field produced by the DC pulse is maximized. ------------------------------------------------- The key idea is to partially demagnetize the billet. To do this, the magnetic field lines from the magnet must oppose magnetic field lines produced by the sides of the billet. The demagnetization process must be done in small steps where feedback about the behavior of the magnetic bubble can be applied to arrive at a goldilocks level of magnetization: not too much and not too little. The capacitor bank should start out energized with only 100 volts worth of energy. Then the magnetic bubble should be checked out after each demagnetization operation to determine if a liquid and highly mobile magnetic bubble has emerged in the center of the billet's sides. This validation process could be automated through a mecanized scan of the total surface area of the magnet aginst a bebchmark. or it could entail rapid eyeballing of the magnetic field lines using magnetic field viewing film https://www.amazon.com/Magnetic-Viewing-Film-Field-Display/dp/B00129CCGS/ref =sr_1_6?ie=UTF8 <https://www.amazon.com/Magnetic-Viewing-Film-Field-Display/dp/B00129CCGS/re f=sr_1_6?ie=UTF8&qid=1488160497&sr=8-6&keywords=magnetic+field+plastic+film> &qid=1488160497&sr=8-6&keywords=magnetic+field+plastic+film Through trial and error, a voltage step up delta increment value should be determined to gradually demagnetize the billet. After establishing this test bed, then we can move on to imposing the activation signel into the billet.
