In order to understand the nature of superconductivity, we suggested a novel idea of "cool electron." To explain superconductivities and compensate for the lack of current theory, a new quantum theory of cold electrons was developed. The essential point is that we embraced electron orbital rotation as an alternative to classical electron spin. It leads to the important conclusion that at low temperatures, the electron is in a flat orbital. The physical mechanism of superconductivities is best explained in this manner. The conditions of electrons will vary dramatically if it is assumed that electrons have motion tracks that can be defined in atoms. After then, the new concept of cold electron is established. This suggests that electrons can detect temperature. The Schrödinger function is, in fact, the function of an ideal electron. The hot electron resembles the ideal electron's electron. As the temperature drops, the electron orbits will definitely deviate from the Schrödinger function and run in a flat one. The orbital geometry of paired electrons changes with temperature, moving from three to two dimensions. The paired cold electron saves a lot of room in the atomic crystal lattice as compared to the common electron's orbital configuration. It laid the groundwork for the phase transition to occur at a low critical temperature.
Author(S) Details
Zhen-hua Mei
Qingdao University of Science and Technology, Qingdao, China.
Qingxian Yu
Qingdao University of Science and Technology, Qingdao, China.
Shuyu Mei
School of Medicine, Shandong University, Jinan, China.
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