Article 7. Molecular Attributes of ‘Revolution’ Motion in Materials/分子‘公转’运动与材料的分子特性
Author: Liu Huan (1983 - ), Master of Science (First Class Honours), The University of Auckland.
Atom is the most primitive material form of elementary particles; in our three-dimensional space, the motion model of elementary particles in atom can be simplified as the rotation of electrons around the nucleus, and the nuclei and electrons are the Yin and Yang poles of matter's magnetic properties respectively; at the same time, the magnetic line on the fourth dimension axis is perpendicular to the three-dimensional space. These magnetic elementary particles cut along the magnetic line on the fourth dimensional axis, thus generating electric charges. The existence of the electromagnetic induction theorem is the transmission pathway of driving force which leads electrons to rotate around the nucleus. The relative motion between positive and negative charged particles in the three-dimensional space produces a current effect. The current direction is perpendicular to the magnetic line on the fourth dimension axis, which is consequently similar to the principle of the motor coil rotation, and pushes the spin motion of the basic particle in the atoms; for molecules with poly-atomic aggregation form, the dark matter on the fourth dimensional axis as an energy binder polymerizes mono-atomic matter forming both Yin and Yang poles of the whole aggregated molecule [2], which makes the cutting motion on magnetic lines of the fourth axis, leading to ‘the revolution movement’. Similarly, the matter in molecular structure makes "revolution" around the geometric center of the magnetic mass line in a molecule; by analogy, the transmission of driving force of both the earth's rotation and the revolution of other galaxies are generated by the electromagnetic induction theorem when the material properties of Yin and Yang poles in three-dimensional space are cutting against the fourth dimensional magnetic line. Further more, the higher the overall polarity in a molecule, the faster the angular velocity of molecules, and consequently the chemistry reaction is more active; moreover, the higher the ratio of total mass to total charge (M / E) in molecules, the slower the angular velocity of molecules, so the chemistry reaction is less active. This also provides the basis for the optimization of synthetic structure of polymers by 3D simulation of molecule movement.
Further discussion: compared with the electron, the radius between the proton and the rotation center in the nucleus is shorter, and the proton rotation speed is higher, so the energy flow intensity of electromagnetic wave is higher, and the transmission speed of electromagnetic wave is faster. The refraction or diffraction of light is caused by the interference influences between the magnetic field on the obstacle surface and the polarity of light wave, which is different from mechanical wave. Therefore, different characteristics of materials with different magnetic field on the surface generates different light refraction or diffraction angles. This is also applicable on the other frequencies of electromagnetic wave. These findings provide basic characters for the synthesis of new materials. As discussed in Figure 1, the vertical red line represents the boundary between medium A (left) and medium B (right); magnetic field B in the medium A is vertical to the magnetic intensity curve (on the plane by axis y and z) of electromagnetic wave; electric field E in the medium A is vertical to the electric intensity curve (on the plane by axis x and z) of electromagnetic wave; in medium A, the transmission direction of electromagnetic wave V is parallel to axis z. Once the electromagnetic waves passes from medium A (left) into medium B (right), the direction of magnetic field B in medium B is different from it in medium A, so that the magnetic field B in medium B alters the transmission direction of electromagnetic wave V, making the magnetic field B in the medium B vertically to the magnetic intensity curve of electromagnetic wave in medium B. This is the mechanism of light refraction, which is also applicable on the light diffraction.
file:///C:/Users/ADMINI~1/AppData/Local/Temp/ksohtml9148/wps1.jpg
Figure 1. The mechanism of light refraction from medium A (left) to medium B (right) with the boundary of vertical red line between them.
译文:原子是基本粒子最原始的物质形态;我们所在的三维空间中,原子中的基本粒子运动模型可以简化为电子围绕原子核做自转运动,原子核与电子为物质磁场属性的阴阳两极;与此同时,第四维度轴上的磁力线与三维空间垂直,阴阳两极基本粒子在第四维度轴的磁力线上做切割运动,从而产生了电荷。电磁感应定理的存在,是电子围绕原子核做自转运动的动力传输原理。三维空间中正负带电粒子相对运动产生电流效应,电流方向垂直于第四维度轴上的磁力线,从而类似于电动机线圈转动原理,推动基本粒子在原子内的自旋运动;对于多原子物质聚合形态的分子,在第四维度轴上的暗物质作为能量粘合剂聚合了单原子物质并且形成整个分子的阴阳两极[2],使得三维空间分子结构中的阴阳极性在第四维度轴上的磁力线的切割运动,进行着“公转”运动。相似的,分子结构中的物质围绕整体分子的质量磁力线的几何中心做“公转”运动;余此类推,地球自转和其它星系公转运动的动力传输原理,都是三维空间中的阴阳两极物质属性与第四维度磁力线做切割运动时电磁感应定理产生。因此,分子中整体极性越高,分子旋转角速度越快,化学反应特性越活跃;不仅如此,分子中的总质量与总体电荷量的比值(M/E)越高,分子旋转角速度越慢,化学反应特性较不活跃。这为通过3D模拟优化高分子化合物提供了依据。
进一步论述:与电子相比,原子核中质子与自转中心之间的半径更小,质子自转角速度更高,因此产生的电磁波能量流密度更大,电磁波传播速率更快。光的折射或是衍射现象是由于障碍物表面磁场与光波极性的干涉作用产生的,这与机械波不同。因此不同特性的材料由于表面磁场不同会产生不同的光的折射或是衍射角度。这种特性对于其它频率电磁波的折射或是衍射也同样适用。这些发现将为新材料研发提供了基础特性。如图1所述,垂直红线表示介质A(左边)与介质B(右边)之间的边界。介质A中的磁场B垂直于电磁波的磁场强度曲线(在y-z轴构成的平面上),介质A中的电磁E垂直于电磁波的电场强度曲线(在x-z轴构成的平面上),在介质A中电磁波V的传播方向与Z轴平行。一旦电磁波V从介质A(左)穿透至介质B(右),在介质B中的磁场B的方向不同于介质A中的磁场B方向,因此介质B中磁场B更改了电磁波V的传播方向,使得介质B中的磁场方向与介质B中传播的电磁波V相互垂直。此类光的折射原理同样适用于光的衍射。
Please note: This is the revised materials in book “Proceedings for Degree of Postgraduate Diploma in Environmental Science (3rd Edition).” published in 2016. Revised on 31/12/2020. This journal article is previously published as: Liu Huan. (2021). Molecular Attributes of 'Revolution' Motion in Materials. Journal of Environment and Health Science (ISSN 2314-1628), which is converted into Journal of Quantum Physics and Materials Chemistry (ISSN2958-4027) . Both Journals belong to the same publisher, Liu Huan. The previous journal article is closed to the public, but the previous reference is still valid. Latest revised on 19/05/2023; 20/05/2023;25/05/2023; 05/06/2023.
References:
[1]. 搜狗百科,共享百科全书/Sogou Baike, Creative Commons.
[2]. Liu Huan. (2021). Van der Waals force and Dark Matter. Journal of Environment and Health Science (ISSN 2314-1628), 2021(02). https://doi.org/10.58473/JQPMC0006
发表于 2021-1-2 15:55:05
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