Planck Speed: the Missing Speed of Physics? Absolute Still Without Breaking Lorentz Symmetry!

European Journal of Applied Physics Pub Date : 2022-01-08 DOI:10.24018/ejphysics.2022.4.1.144

E. Haug

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引用次数: 6

Abstract

Today, the speed of light is one of the cornerstones of modern physics. It is the maximum speed limit for transferring information, and plays a very central role in relativity theory. It also seems to be the same as the assumed and measured speed of gravity (gravitons and/or gravitational waves). We are not questioning the speed of light, as we indeed think it is the maximum speed limit and that it is identical to the speed ofgravity, but we also think photons lead us to a second speed limit, which we will term the Planck speed. Photon-photon collisions are part of modern physics, but what is not discussed is the speed of two photons during the very moment of a photon-photon collision. How can photons move during a collision? Or, assumea photon is reflected by a mirror; to do so it must collide with the building blocks of the mirror, yet how can it be moving during the very collision point? Also, modern physics assumes mass can be created in a photon-photon collision. We suggest this mass is the Planck mass particle and that it only lasts one Planck time, so when two photons collide, we will claim they must stand still for the direct observer. That is, we suggest thatthe speed of the Planck mass particle is always zero, but that this zero-velocity can only last for one Planck time. That it only lasts one Planck time means it will not break with the relativity principle or Lorenz symmetry, or at least what we can call weak Lorentz symmetry. We will show that the missing Plank mass particle is the very collision point between two photons, and that this is fully in line with predictions in other researchers’ findings in relation to the possible photon mass. This new view seems to solve the missing mass-gap, and seems able to unify gravity with quantum mechanics. This again seems to unify photons with mass, because one of the long-outstanding questions in physics is whether photons have mass or not. In addition, we showhow to find, in a very simple way directly from gravitational observations, lp/tp= cg = c, which is the upper speed limit (the speed of light and gravity) independent of any knowledge of G or ~ or c.

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普朗克速度:物理学中缺失的速度?不打破洛伦兹对称的绝对静止!

今天，光速是现代物理学的基石之一。它是传递信息的最大速度限制，在相对论中起着非常重要的作用。它似乎也与假设和测量的重力(引力子和/或引力波)速度相同。我们并不是在质疑光速，因为我们确实认为光速是最大的速度限制，它与引力的速度相同，但我们也认为光子会把我们引向第二个速度限制，我们称之为普朗克速度。光子-光子碰撞是现代物理学的一部分，但没有讨论的是在光子-光子碰撞的非常时刻两个光子的速度。光子如何在碰撞中移动?或者，假设光子被镜子反射;要做到这一点，它必须与镜子的构建块碰撞，然而，它是如何在碰撞点移动的呢?此外，现代物理学假设质量可以在光子-光子碰撞中产生。我们认为这个质量是普朗克质量粒子，它只持续一个普朗克时间，所以当两个光子碰撞时，我们会声称它们对直接观察者来说必须静止不动。也就是说，我们认为普朗克质量粒子的速度总是为零，但这个零速度只能持续一个普朗克时间。它只持续一个普朗克时间，这意味着它不会打破相对性原理或洛伦兹对称，或者至少我们可以称之为弱洛伦兹对称。我们将证明，缺失的普朗克质量粒子是两个光子之间的碰撞点，这与其他研究人员关于可能的光子质量的预测完全一致。这种新观点似乎解决了缺失的质量间隙，似乎能够将引力与量子力学统一起来。这似乎再次将光子与质量统一起来，因为物理学中一个长期悬而未决的问题是光子是否有质量。此外，我们展示了如何用一种非常简单的方法直接从引力观测中发现lp/tp= cg = c，这是与G或~或c的任何知识无关的速度上限(光和引力的速度)。

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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European Journal of Applied Physics

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