More... The Mandela bullot is flat and square with a large surface area. This flat topology with a large surface area might permit a maximum of magnetic dipoles to form on the surface of the Mandela bullot. I would like to know what type of gas filled the black box...is it protium or deuterium or air?
On Sun, Feb 12, 2017 at 8:09 PM, Axil Axil <janap...@gmail.com> wrote: > [image: Inline image 1] > The Manelas Device functional diagram > > > > On Sun, Feb 12, 2017 at 7:58 PM, Axil Axil <janap...@gmail.com> wrote: > >> It might be that the pulsed current of the 137 kilohertz square wave >> input current produces a magnetic dipole with a large instantaneous power >> factor because the current is produced by a square wave like the Brillouin >> method. The 24 volt constant current also produces heat and the strontium >> ferrite magnet is heat resistant. The maximum operating temperature of the >> magnet is 250C and the Curie temperature is 450C, With that high >> temperature operating capacity, coherent magnetically based Surface plasmon >> polaritons may form under the influence of the magnetic dipole motion that >> localize around the magnetic field lines as heat photons become entangled >> with electrons dipoles. >> >> If these magnetic polaritons become coherent, these polaritons may >> produce enough magnetic power to destabilize the nuclei of the gas above >> the surface of the magnet inside the Mandela's Device black box. >> >> On Sun, Feb 12, 2017 at 6:28 PM, Brian Ahern <ahern_br...@msn.com> wrote: >> >>> The Manelas billet is strontium ferrite and is very high electrical >>> resistivity. This eliminates eddy currents as a loss mechanism >>> >>> >>> ------------------------------ >>> *From:* Axil Axil <janap...@gmail.com> >>> *Sent:* Sunday, February 12, 2017 6:18 PM >>> *To:* vortex-l >>> *Subject:* [Vo]:Regarding what BOB COOK THINKS ABOUT THE NAE >>> >>> Regarding what BOB COOK THINKS ABOUT THE NAE >>> >>> >>> "Note my recent comment regarding the Manelas Device reflecting your >>> notice about the discovery of time crystals. There may be a connection with >>> the magnetic materials used in the device. >>> >>> Separately, I would note that the design of NAE’s may require a >>> structure which allows high magnetic fields (10^12 –10^16 Tesla.) >>> Structures that are 1 or 2 dimensional may be the key, with the 1-D NAE >>> supporting LENR+, because it causes the reaction in a confined space and >>> maintains the 1-D characteristic for repeated reactions upon arrival of >>> reactants—H or D or Li or whatever." >>> >>> There is a branch of physics called "QCD in strong magnetic fields" that >>> has conducted workshops on what a strong magnetic fields can do to a >>> nucleus. >>> >>> http://homepages.uni-regensburg.de/~eng14891/qcdB_workshop/program.shtml >>> QCD in strong magnetic fields - uni-regensburg.de >>> <http://homepages.uni-regensburg.de/~eng14891/qcdB_workshop/program.shtml> >>> homepages.uni-regensburg.de >>> Monday 12 November; 09:00 - 09:40: Berndt Müller: When QCD meets QED: >>> 09:40 - 10:20: Vladimir Skokov: Magnetic field in HIC and anisotropy of >>> photon production >>> >>> >>> >>> and also by another name "Workshop on Magnetic Fields in Hadron Physics" >>> >>> http://www.ictp-saifr.org/wp-content/uploads/2015/05/all-abs >>> tracts_logo.pdf >>> Workshop on Magnetic Fields in Hadron Physics ICTP/SAIFR ... >>> <http://www.ictp-saifr.org/wp-content/uploads/2015/05/all-abstracts_logo.pdf> >>> www.ictp-saifr.org >>> Workshop on Magnetic Fields in Hadron Physics . ICTP/SAIFR - São Paulo, >>> BR . May 9 - 13, 2016 . List of Abstracts . MONDAY – May 9 . Uses and >>> misuses of the NJL ... >>> >>> >>> >>> One posit of this field is that in a magnetic field of (10^12 –10^16 >>> Tesla.), Localization of (anti-)quark orbits by magnetic field enhances >>> chiral symmetry breaking effect of attractive interactions. >>> >>> See >>> >>> http://homepages.uni-regensburg.de/~eng14891/qcdB_workshop/p >>> df/QCDB_Mueller.pdf >>> >>> QCD in strong magnetic fields >>> >>> Charged vector mesons can condense in a superstrong magnetic field. This >>> superstrong magnetic field can be considered a magnetic catalyst that >>> produces charge parity violation thereby producing strange quarks and their >>> mesons. >>> >>> The question then becomes, can Surface plasmon polaritons(SPP) amplify >>> light/electron entanglement to the point where magnetism reaches very high >>> strength, enough to produce a magnetic catalyst of mesons. >>> >>> When it comes to bose condinsation through ultra dense hydrogen as a way >>> to amplify SPPs through superradiance, what matters is the number of SPPs >>> that aggregate in that condinsate. >>> >>> An analogy of the additive aggregation principle is how 8,000 AA lithium >>> batteries can produce enough power to propel a Tesla for over 200 miles. >>> >>> Quantum mechanics can do unexpected things. >>> >>> When protons and neutrons fall apart into mesons, the final result is a >>> boatload of electrons that are fabricated from decaying nuclear matter. >>> This is where the current observed in the Manelas Device might come from. A >>> large anisotropic magnet might be strong enough to produce electrical power >>> strong enough and properly focused to tear apart nuclear matter. >>> >> >> >
