三维洛伦兹不变速度

Symmetry Pub Date : 2024-09-02 DOI:10.3390/sym16091133
James M. Hill
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引用次数: 0

摘要

洛伦兹不变性是狭义相对论的基础,众所周知,能量公式和相对速度公式在洛伦兹变换下是不变的。在这里,我们确定了在最一般的完全三维洛伦兹变换下自动不变的三维速度场的四个任意函数的函数形式。对于一般的三维运动,使用矩形直角坐标 (x,y,z),我们分别确定了 x、y 和 z 方向上三个速度分量 u(x,y,z,t)、v(x,y,z,t) 和 w(x,y,z,t) 的一阶偏微分方程。这些偏微分方程以及连接能量和动量的相关偏微分关系与洛伦兹不变的能量-动量关系完全吻合,似乎是以前文献中没有给出过的。我们确定了在三维洛伦兹变换下自动不变的三维速度场的函数形式的空间和时间依赖性。一个有趣的特例是,粒子路径的速度大小是光速。这表明在 "快车道 "上存在着丰富的可能性。
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Three-Dimensional Lorentz-Invariant Velocities
Lorentz invariance underlies special relativity, and the energy formula and relative velocity formula are well known to be invariant under a Lorentz transformation. Here, we determine the functional forms in terms of four arbitrary functions for those three dimensional velocity fields that are automatically invariant under the most general fully three-dimensional Lorentz transformation. For general three-dimensional motion, using rectangular Cartesian coordinates (x,y,z), we determine the first-order partial differential equations for the three velocity components u(x,y,z,t), v(x,y,z,t) and w(x,y,z,t) in the x−, y− and z−directions respectively. These partial differential equations and the associated partial differential relations connecting energy and momentum are fully compatible with the Lorentz-invariant energy–momentum relations and appear not to have been given previously in the literature. We determine the spatial and temporal dependence of the functional forms for those three-dimensional velocity fields that are automatically invariant under three-dimensional Lorentz transformations. An interesting special case gives rise to families of particle paths for which the magnitude of the velocity is the speed of light. This is indicative of the abundant possibilities existing in the “fast lane”.
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