Since the superconducting resistance waszero, could this current be maintained for a long time? Later, someone re-didthis experiment in a more refined way, using a magnetically strong needleplaced in the center of a lead ring, and proved that the current in the coilwas not found to decay in the slightest way after several years. The extremelylow temperature and the rotation of the loop current with the magnetic lines offorce out of the south pole and in from the north pole are typical of thephenomenon of three-spin space. That is, the triple-spin quantum number,where the body-spin corresponds to the temperature, the surface-spin to theelectric current, and the line-spin to the magnetic field. Triple spin is aninherent property of matter in the microscopic realm, but no one in the"scientific and technological community" has made any connection tothis hidden order since Onis 109. Considering superconductivity as a phenomenonof soft matter analogous to granular matter, there is a way to relate it to thetheory of triple spins, for example, by drawing a grid of longitudinal andlatitudinal lines on a torus-like body, which we call a transposon. That is,the class circle body is divided into ring segments, ring segments and dividedinto grids, made a kind of magic like the magic way of the magic ring device;of course, this grid can be large or small, any take a grid or a point can bein the class circle body or with the class circle body, around the centercircle line in the class circle body is composed of the center of the circle ofthe axis of the rotation, or around the center circle line rotation. In theclass circle body, if this "particulate matter" similar to the gridand the point block is called the transposer, this transposer type particulatematter is also both similar to the solid, flow and like liquid, gas, and thereis a group effect of the movement, as well as the shape of the grid pattern andthe layout of the pattern is regular. Generally speaking, the lattice for ordinaryline spins is square, and the lattice for extraordinary line spins isprismatic. If the motion of the transposon group effect is set up to square andprismatic respectively, the two kinds of transposon lattice, such as square,both left and right movement and up and down movement; such as prismatic, butcan not be, because of this vertical and horizontal movement will be the tip tothe tip, the two oblique edges of the pressure at the same time, can not beneatly movement down, only for oblique movement. But it is not correct to saythat a square carousel pattern must move in a plain line rotation, and aprismatic carousel pattern must move in an uneven line rotation. The reason isthat it is the number of wraps, i.e., the number of consecutive edges of thediagonal mesh that are at least one closed line around the ring, that iscrucial in distinguishing a plain line spin from an uneven line spin. Generally speaking, the square mesh block isparallel to the side of the center circle line in the class circle, can onlymake ordinary line spin, also can make face spin alone. Prismatic mesh block orsquare is diagonally arranged, whether it is for non-trivial line spin, we haveto check whether there is a number of circles; but one thing is certain, theycan not be alone for the surface spin, its surface spin is combined with theline spin. This locking of the lattice shape and pendulum determines that thetransposon motion is faceted, which is linked to the fact thatsuperconductivity does not depend very much on the three-dimensional couplingbetween the superconducting thin layers, and expresses a more obvioustwo-dimensional mechanism. Second, just as playing hula hoops can moveup and down the body, the three-spin image also illustrates this stricttwo-dimensional restriction in that for an electron pair of such smallthree-spin loops, in the presence of line-spinning streamers crossing theplanes and at temperatures as low as Tc or below, it can also tunnel coherentlyfrom one planar plane to the other through the Josephson effect, whereas itcannot do so for a single electron. Based on the above study that the optimalnetwork for a three-rotation motif is square or prismatic, the search forroom-temperature atmospheric-pressure superconductors should begin withmaterials in the class of hierarchical rhombohedral lattices, since theyapproach an ideal macroscopic quantum effect. If the current is passing throughsuch crystalline surfaces, then when connected to an external circuit, itconstitutes a loop state, and the formation of nontrivial line spins is easy onthis circuit of matter. The nontrivial line spins have combined the face andline spins, and this is shown precisely by the macroscopic quantum phenomena ofelectricity and magnetism. The second body spin, roughly speaking, is aflipping, which is connected with macroscopic temperature effects; the higherthe temperature, the greater the collision and flipping, which is not conduciveto the coherence and coordination of electron pairs. So room temperatureatmospheric superconductivity from the macroscopic point of view, to choose thelattice is not conducive to flipping. The triangular network is not as orderly asthe square motion on the face and line spins has been ruled out, and the squareis not easy to turn over because it has the least rounding compared with othersquare polygons, so from the macroscopic mathematical analysis of the threespins, the layered rhombohedral crystal dominates for this type ofsuperconductivity.
|