基于正负磁极子相互作用的统一相位场论与实验数据分析
Unified Phase Field Theory Based on the Interactions between Positive and Negative Magnetic Poles and Experimental Data Analysis
摘要: 近百年来,许多物理学家对“爱因斯坦场方程”、“量子场论”、“V-A”理论、“规范场论”、“量子电动力学”、“量子色动力学”、“标准模型”,以及“弦理论”等,进行了广泛而深入地研究,为研究自然界四种基本力的统一提供了学术思想和实验数据。本文提出基本粒子是由正负磁极子相互作用构成的磁量子场这一假设,试图论述基于正负磁极子相互作用的统一相位场理论,建立统一相位场曲率张量方程,并运用相关实验数据进行检验,真正实现电磁力、强力、弱力和引力的统一。引力、电磁力、强力和弱力,皆因正负磁极子相互作用而产生,是正负磁极子相互作用的四种表现形式。粒子磁极子场(引力场)对其磁极子的凝聚力为引力,粒子磁极子场在外场(引力场)中的自旋力为电磁力,中子和质子的正性磁极子环同轴自旋的结合力为强力,中子的外层正性磁极子环的衰变为弱力。
Abstract: In the past hundred years, many physicists conducted extensive and in-depth research on “Einstein’s field equation”, “Quantum field theory”, “V-A” theory, “Gauge field theory”, “Quantum electrodynamics”, “Quantum chromodynamics”, “Standard models” and “String theory”, and provided academic ideas and experimental data for studying the unification of four fundamental forces in nature. This paper proposes a hypothesis that the elementary particles is the magnetic quantum field composed of the interactions between positive and negative magnetic poles, and attempts to discuss the unified phase field theory based on the interactions between positive and negative magnetic poles, and establishes the curvature tensor equation of unified phase field, and tests theory and curvature tensor equation of unified phase field with relevant experimental data, and thus really achieves the unification of electromagnetic force, strong force, weak force and gravitational force. The gravitational force, electromagnetic force, strong force and weak force are all produced from the interactions of positive and negative magnetic poles, which are the four kinds of forms of the interactions between positive and negative magnetic poles. The cohesive force of elementary particle’s magnetic poles field (Gravitational field) to its magnetic poles is the gravitational force. The spin force of elementary particle’s magnetic poles field in external field (Gravitational field) is the electromagnetic force. The binding force of positive magnetic poles ring coaxial spin in neutron and proton is the strong force. The decline of neutron’s outer positive magnetic poles ring is the weak force.
文章引用:吴先金. 基于正负磁极子相互作用的统一相位场论与实验数据分析[J]. 现代物理, 2020, 10(4): 61-72. https://doi.org/10.12677/MP.2020.104007

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