The Formation of the Electronic Tornado is the Basis of Superconductivity
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DOI: https://doi.org/10.30564/jcsr.v3i1.2780
Abstract: The space-time ladder theory reveals that the formation of electronic tornadoes, or the formation of electronic dissipative structures, to be precise, the enhancement of electronic Energy Qi field is the basis of superconductivity. The surrounding area of the electronic tornado is expanding, which is the basis of the Meissner effect, and the center is contracting, which is the basis of the pinning force. When the attractive force of the Energy Qi field is greater than the Coulomb repulsive force, the electrons form a Cooper pair and release dark energy into virtual space-time. When the dark energy increases to a certain extent, the virtual space-time frees the Cooper pair and forms an electron-virtual space-time wave, which fluctuates freely in the superconducting material, which is the basis for the superconducting resistance to be zero. This is similar to the principle of a hot air balloon. The virtual space-time is hot air and the electron pair is a hot air balloon device. Conductor electrons are free and easy to emit dark energy, resulting in insufficient dark energy, and it is not easy to form electron-pair virtual space-time waves, so the superconducting critical temperature is very low. This is because the emission coefficient of the conductor is too high. Insulator electrons are not easy to emit dark energy and easily form electron-pair virtual space-time waves. Therefore, the superconducting critical temperature is slightly higher because of the low emission coefficient of the insulator. The solution of the Qi-space-time wave equation, that is, the coherence coefficient, is an important factor in superconductivity. In addition, the conditions under which tornadoes form are also an important basis for superconductivity. Finally, it is emphasized that the coherence coefficient and prevention of dark energy emission are the two most important elements for preparing superconducting materials. References:[1] Binggong Chang. A Collection of Space-Time Ladder Theories-Matter·Dark Matter·Dark Energy. (Language: Chinese. ISBN-10: 1618965638. ISBN-13: 978-1618965639. ASIN: B075WKRZP5) [2] Binggong Chang. Interpretation of Double-Slit Experiment by Space-Time Ladder Theory-Essence of Delayed Choice Quantum Eraser Experiment. Modern physics, 2019, 9(6). https://www.hanspub.org/journal/PaperInformation.aspx?paperID=32500 [3] Haihu Wen. Research progress of new high-temperature superconducting materials. Journal of Materials Research, CHINESE JOURNAL OF MATERIALS RESEARCH. 2014, 29(4). https://www.cjmr.org/article/2015/1005-3093/1005-3093-2015-29-4-241.shtml [4] Dongsheng Yang, etc., Thermal conductivity of dual-gap superconductor MgB2. Chinese Journal of Physics, 2003, 52(3). http://wulixb.iphy.ac.cn/fileWLXB/journal/article/wlxb/2003/3/PDF/w20030332.pdf [5] Zhenqi Hao et al, Anomalous doping evolution of superconductivity and quasiparticle interference in Bi2Sr2Ca2Cu3O10+δ trilayer cuprates,.arXiv.org, arXiv:2012.04206. https://arxiv.org/abs/2012.04206 [6] Zengyi Du, etc., Unified understanding of the energy gap structure and mechanism of iron-based superconductors. Physics, 2018, 47 (1). [7] Wencan Jiang, Hua Chen, Weibin Zhang. First-principles study of phonon spectrum and specific heat capacity of TATB crystal. Acta Phys. Sin., 2016, 65(12): 126301. http://wulixb.iphy.ac.cn/article/id/67510