A Novel Explanation of the Meissner Effect and New Applications | Chapter 2 | Fundamental Research and Application of Physical Science Vol. 7

 In the current quantity description of the Meissner effect, a superconducting material behaves accurately like a perfect diamagnetic material in the presence of an extrinsic magnetic field. However, when we place a superconductor above a bait, we observe a high ground of the superconductor above the magnet. But when ordering a perfect diamagnetic material above a magnet, no high ground is observed. In the superconducting state, the spins or attractive spin moments of the electrons (free electrons) are joined. The coupling of these spin importance leads to the creation of a magnetic field of currents around the superconductor. When it is established in an extrinsic magnetic field, the magnetic field of currents of the superconductor interacts accompanying the external magnetic field of currents, hence the Meissner effect performs. The classical writing of the Meissner effect used in this place article discloses the difference in behaviour betwixt the superconductor and the perfect diamagnetic in the presence of an outside magnetic field.  We have proved here that the Meissner effect is nothing in addition to an electromagnetic interaction betwixt the magnetic field designed by the superconductor and the magnetic field of currents of the magnet. The electromagnetic interplay between the magnetic field of currents of a superconductor and that of a bait during a Meissner effect is fundamentally similar to the electromagnetic interplay between two free electrons of the superfluid vapor.  The study also showed that the expansion of outer space is only a Meissner effect between superconducting dark matter and leading attractive fields. We also identified that this expansion is increased because the gravitational force middle from two points dark matter and the stars about it decreases as these stars move from the superconducting dark matter.  We also projected a new method of detached sensing anticipate where the superconducting subsidiary is perpetually levitating on the midnight side of the earth and a new and more persuasive way to find new particles through a superconducting indicator levitating in the upper atmosphere utilizing this classical writing of the Meissner effect.

Author(s) Details:

Elie W’ishe Sorongane,
Physics Department, University of Kinshasa, Kinshasa, Democratic Republic of the Congo.

Please see the link here: https://stm.bookpi.org/FRAPS-V7/article/view/11117