Superluminality and Finite Potential Light-Barrier Crossing

T. G. Gerlitz
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引用次数: 2

Abstract

Superluminal movements are subject of discussion since many decades. The present work investigates how an electrical charged real matter particle can traverse the energy barrier at the speed of light in vacuum. Here, parity reflexion takes place with respect to space, time, and mass. It is postulated this traversal can occur by a jump-over supported by electrical attraction between the subluminal particle and its virtual superluminal co-particle producing an electrical field opposite in sign. The jump over the light barrier implies a zero in time and here the particle becomes undetectable in position and mass. The result of the calculation shows two exclusive speeds where light-barrier crossing can occur from a sub- to a superluminal state or reverse. This leads to three different kinds of objects, where the first is denoted a subluminal mono-particle Bradyon, the second a superluminal mono-particle Tachyon, and the third a luminal twin Luxon consisting of two parts absolutely complementary in their states alternating between the both speeds, those touch the light-barrier, and traveling with an average of light-speed. A relation between the distance of a subluminal particle to its superluminal co-particle and the wave-length of the system can be manifested. The constant in speed of light is discussed.
超光度和有限势光垒穿越
几十年来,超光速运动一直是讨论的主题。目前的工作是研究带电的真实物质粒子如何在真空中以光速穿越能垒。在这里,宇称反射是相对于空间、时间和质量发生的。假设这种穿越可以通过亚光速粒子和它的虚超光速共粒子之间的电吸引力支持的跳变来实现,从而产生一个符号相反的电场。越过光障意味着时间为零,在这里粒子的位置和质量变得无法检测。计算结果表明,光障穿越可以发生在亚光速到超光速或相反的两种不同速度。这导致了三种不同类型的物体,其中第一种被称为亚光速的单粒子布氏子,第二种是超光速的单粒子塔奇子,第三种是光速的孪生卢克松,由两部分组成,它们的状态绝对互补,在两种速度之间交替,它们接触光障,以光速的平均速度行进。亚光速粒子到超光速共粒子的距离与系统的波长之间的关系可以得到证明。讨论了光速的常数。
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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