The Higgs mechanism is a type of superconductivity which occurs in the vacuum. It occurs when all of space is filled with a sea of particles which are charged, or, in field language, when a charged field has a nonzero vacuum expectation value. Interaction with the quantum fluid filling the space prevents certain forces from propagating over long distances (as it does in a superconducting medium; e.g., in the Ginzburg–Landau theory).
A superconductor expels all magnetic fields from its interior, a phenomenon known as the Meissner effect. *This was mysterious for a long time, because it implies that electromagnetic forces somehow become short-range inside the superconductor. * Short range effects means MASS. Photon gain mass in a superconductor. On Thu, Nov 5, 2015 at 8:17 PM, David Roberson <[email protected]> wrote: > The field is repulsed by the flowing of current. That induced current > balances out the incoming field. > > Dave > > > > -----Original Message----- > From: Axil Axil <[email protected]> > To: vortex-l <[email protected]> > Sent: Thu, Nov 5, 2015 7:59 pm > Subject: Re: [Vo]: Evidence for ultra-dense deuterium > > Magnetic repulsion in superconductivity is caused by the generation of > mass by the superconductor in the photon. This is the same mass production > mechanism that is seen in the higgs field were mass is produced in the W > boson. > > On Thu, Nov 5, 2015 at 7:49 PM, David Roberson <[email protected]> wrote: > >> From what I recall the magnetic field repulsion is due to current >> flowing and not on an individual atom basis. That would imply that no >> extra repulsion would be seen for atoms embedded within the iron. >> >> Dave >> >> >> >> -----Original Message----- >> From: Bob Higgins <[email protected]> >> To: vortex-l <[email protected]> >> Sent: Thu, Nov 5, 2015 6:39 pm >> Subject: Re: [Vo]: Evidence for ultra-dense deuterium >> >> Jones, >> >> Even if true that H(-1) exists as a superfluid/RTSC (and Winterberg says >> that the ultra-dense form only occurs with deuterium), then it is highly >> likely that it would be a type II superconductor, like all of the >> superconductors above about 40K. The type II superconductors pin a >> magnetic field inside it if the field was there when the superconducting >> state formed. So, you wouldn't get the instant repulsion. >> >> On Thu, Nov 5, 2015 at 3:56 PM, Jones Beene <[email protected]> wrote: >> >>> Of interest… >>> >>> In a 2014 paper, Holmlid says: “Ultra-dense hydrogen H(-1) is a quantum >>> material and the first material which is superfluid and superconductive at >>> room temperature. This has been shown in detail for the deuterium form >>> D(-1).” >>> >>> Comment: >>> As a RTSC, the dense material H(-1) will be subject to the Meissner >>> effect. If it is created on a ferromagnetic catalyst which has permanent or >>> applied magnetic field, which is possible to accomplish with iron oxide as >>> the fill, then H(-1) should be repelled as soon as it is made. >>> >>> The H(-1) can made within a translucent alumina tube filled with Shell >>> 105 and hydrogen, using photons shining into the tube, so as to create SPP >>> on the interfacial ID surface of the tube. The H(-1) should slowly migrate >>> into the walls of the alumina. This should happen as soon as it is formed >>> due to Meissner repulsion. Laser light should be avoided in favor of >>> diffuse monochromatic light during the fuel build-up stage. It would be >>> beneficial to cool the tube as much as possible at this stage, possibly >>> using a cold plate. The alumina matrix would be effectively porous to H(-1) >>> at only a few picometers in diameter. >>> >>> This is concievably an effective way to make and store the H(-1) for >>> later use. >>> >>> >>> >> >> >
