tag:blogger.com,1999:blog-326167780677397310.post8733816028064328827..comments2024-03-27T21:35:04.988-07:00Comments on EGO OUT: FEB 12, 2017 LENR LEARNING FROM GOING BEYOND LIMITSGeorgina Popescuhttp://www.blogger.com/profile/04628821029016016988noreply@blogger.comBlogger4125tag:blogger.com,1999:blog-326167780677397310.post-23730180099110325322017-02-13T05:53:12.546-08:002017-02-13T05:53:12.546-08:00Dear Sam,
very fine ones, gracis but difficult to...Dear Sam,<br /><br />very fine ones, gracis but difficult to conect to LENR just now.<br />peterAnonymousnoreply@blogger.comtag:blogger.com,1999:blog-326167780677397310.post-2345931354961220692017-02-13T05:34:01.738-08:002017-02-13T05:34:01.738-08:00https://knowridge.com/2017/02/next-generation-grav...https://knowridge.com/2017/02/next-generation-gravitational-wave-detectors/<br /><br />http://www.realclearscience.com/2017/02/13/we_owe_a_great_debt_to_dark_matter_274746.htmlsam northhttps://www.blogger.com/profile/13268558018307793474noreply@blogger.comtag:blogger.com,1999:blog-326167780677397310.post-60614324758050586162017-02-12T17:24:06.554-08:002017-02-12T17:24:06.554-08:00Regarding the Manelas Device
It might be that the...Regarding the Manelas Device<br /><br />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. The resistance to demagnetization of the ferrite magnets goes up with temperature. 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 magnetic dipoles.<br /><br />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. 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?<br /><br />The Manelas Device functional diagram as follows: <br /><br />https://encrypted-tbn2.gstatic.com/images?q=tbn:ANd9GcS8Blv8hf3Hi3O10TDZ9hlEH4IzLx955jQus-EbpsLK7_Qgyijb<br />Axilhttps://www.blogger.com/profile/07190120527431077518noreply@blogger.comtag:blogger.com,1999:blog-326167780677397310.post-49297088652786720772017-02-12T15:04:10.194-08:002017-02-12T15:04:10.194-08:00Regarding what BOB COOK THINKS ABOUT THE NAE
&qu...Regarding what BOB COOK THINKS ABOUT THE NAE<br /><br /><br />"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.<br /><br />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."<br /><br />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.<br /><br />http://homepages.uni-regensburg.de/~eng14891/qcdB_workshop/program.shtml<br /><br />and also by another name "Workshop on Magnetic Fields in Hadron Physics" <br /><br />http://www.ictp-saifr.org/wp-content/uploads/2015/05/all-abstracts_logo.pdf<br /><br />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.<br /><br />See<br /><br />http://homepages.uni-regensburg.de/~eng14891/qcdB_workshop/pdf/QCDB_Mueller.pdf<br /><br />QCD in strong magnetic fields <br /><br />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.<br /><br />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. <br /><br />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. <br /><br />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. <br /><br />Quantum mechanics can do unexpected things.<br /><br />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.<br /><br />Axilhttps://www.blogger.com/profile/07190120527431077518noreply@blogger.com