Magnetism: Further Proof of Wave Particle Duality

Open Journal of Microphysics Pub Date : 2023-01-01 DOI:10.4236/ojm.2023.133005

Bhekuzulu Khumalo

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引用次数: 1

Abstract

The question of what magnetism is vital to quantum physics. We know what all other quantum phenomenon is, but we did not know what magnetism is. It is not enough to say it is a force because of a charge. That force must be something, for consistencies sake it had to be tested. This paper was written in order to confirm the results that were received in the experiments that took place that led to the paper “Magnetism: Insights from the Thomas Young Experiment” where it was concluded the magnetic phenomenon is both a particle and a wave. Will different interference patterns confirm a khumalon and wave like behaviour? The khumalon is the name of the particle associated with magnetic phenomenon. This paper concludes by confirming what was discovered in mentioned paper. Magnetism organizes into a wave no matter the interference. Understanding this reality, it allows us to understand what is happening with simple magnetic interactions. When like poles meet because they can not occupy the same space they push each other. Opposite poles are antiparticles to each other and annihilate each other. South pole scientifically speaking is not attracted to the north pole, the reason why the magnets slam each other is because they are closing a magnetic vacuum caused by the particles annihilating each other. We can now start theorizing on why a lodestone attracts iron because we now know we are dealing with a particle.

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磁性:波粒二象性的进一步证明

什么磁性对量子物理学至关重要。我们知道其他的量子现象是什么，但我们不知道什么是磁力。说它是一个力是不够的，因为它是一个电荷。这种力量必须是某种东西，为了一致性，它必须被测试。这篇论文是为了确认在实验中得到的结果，这些结果导致了论文“磁性:托马斯·杨实验的见解”，在该实验中得出的结论是，磁性现象既是粒子又是波。不同的干涉模式会证实库玛龙和波状行为吗?库马龙是与磁性现象有关的粒子的名称。本文的结论是对上述论文的发现进行确认。不管有什么干扰，磁都能形成波。理解了这个事实，我们就能理解简单的磁相互作用到底发生了什么。当相似的极点相遇时，因为它们不能占据相同的空间，它们会相互推动。相反的两极是彼此的反粒子，彼此湮灭。科学地说，南极不被北极吸引，磁体相互撞击的原因是因为它们正在关闭由粒子相互湮灭引起的磁真空。我们现在可以开始理论化为什么磁石吸引铁因为我们现在知道我们在处理一个粒子。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Open Journal of Microphysics

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