Classical Physics

1912 Submissions

[9] viXra:1912.0191 [pdf] submitted on 2019-12-10 06:33:09

Radiation Damping of a Rotating Dipole

Authors: Radi. I. Khrapko
Comments: 7 Pages. Optik. In Press. Other journals rejections included

Jefimenko's generalization of the Coulomb and Bio-Savard laws is used to calculate the reaction of the radiation on the rotating electric dipole. It is found that the energy taken from the dipole is equal to the recognized value of the radiated energy. At the same time, it is confirmed that the angular momentum flux exceeds the generally accepted value by the spin radiation not seen before.
Category: Classical Physics

[8] viXra:1912.0176 [pdf] submitted on 2019-12-09 18:04:35


Authors: Ldl
Comments: 41 Pages.

The purpose of this paper is to demonstrate a concept which leads to an intuitive and symmetrical interplay between charged and neutral bodies. The concept of directional space. The link between gravitational, charged and magnetic fields will be discussed.
Category: Classical Physics

[7] viXra:1912.0158 [pdf] replaced on 2019-12-09 14:13:38

Orbiting Explains Gravity

Authors: Hans van Kessel
Comments: 10 Pages.

This manuscript identifies the cause of gravity. Based on this cause the gravitational force is quantified. This leads to a correction of Newton’s gravitational equation for the (very) short distance: instead of an ever growing strength –up to infinity when the distance between two objects approaches 0- we will actually find a finite repelling force instead. This manuscript concludes with 2 case studies that support the here presented outcome for gravity, and with a third case study that may allow verification.
Category: Classical Physics

[6] viXra:1912.0099 [pdf] submitted on 2019-12-05 09:28:35

On the Nature of Time

Authors: Marc Kießling
Comments: 3 Pages.

This paper describes the coherence of time, velocity and covered distance. Contrary to believe, time is not a universal property of nature but an interpretation of motion. If we observe an object 1, we can determine its velocity by putting its covered distance in relation to the covered distance of an object 2. In this case the covered distance s 2 of an object 2 equals the required time of object 2. This means that , if 2 covered distances are putt in relation, we can interpret their value as velocity of one of these objects and the covered distance in the denominator as time (s2=t). Therefore we get the equation: v1= s1/s2.
Category: Classical Physics

[5] viXra:1912.0065 [pdf] replaced on 2019-12-07 17:27:10

Antena Maxwell para VHF

Authors: Carlos Alejandro Chiappini
Comments: 9 Pages.

La parte irradiante de la antena Maxwell para VHF es un disco plano de 327 milímetros de diámetro. Un transductor especial transfiere energía entre el disco y la línea de alimentación proveniente del equipo. Entre la salida del transmisor y el disco irradiante no existe continuidad galvánica de tipo alguno. El rendimiento es plenamente satisfactorio.
Category: Classical Physics

[4] viXra:1912.0027 [pdf] submitted on 2019-12-02 14:14:55

Effective Asteroid Deflection Through Impulsive Influence by the Use of a High-Thrust Plasma-Propulsion Driven Platform

Authors: Danny Kirmse
Comments: 5 Pages.

One of the most significant threats from outer space is a massive celestial object with a path crossing the earth’s solar orbit. It is obvious; from a statistic point of view such an event will be rather unlikely. But it can happen, and the consequences would be dramatic. A threat is always scaled by probability and effect. And in sum it is worth to be prepared, when the probability may be low but the potential expected effect is an extensive destruction of human habitat. In general, there are two different opportunities to impact an asteroid and its orbit. One way is to try to destroy the whole asteroid by conventional or even nuclear explosives. But this procedure involves the risk that the number and sizes of the resulting pieces of the asteroid and their trajectories are almost not calculable. Therefore, it is unpredictable if one is decreasing the risk of an earth impact or even increasing it. The other way is to deflect the orbit of the asteroid and to prevent hereby a crossing with the solar orbit of the earth. Without assessing the chance of success, it seems clear that the approach of deflecting will at least not increase the threat compared with the one of destruction.
Category: Classical Physics

[3] viXra:1912.0021 [pdf] replaced on 2019-12-03 16:08:59

Electric Field and Divergence Theorem

Authors: Eric Su
Comments: 2 Pages. Note that the author does not read Disqus comments here, please respond by email. Including a list of publications is also a healthy gesture.

The divergence theorem states that the surface integral of the flux is equal to the volume integral of the divergence of the flux. This is not true if there is singularity in the volume integral. One example is the electric field flux described by Coulomb's law. Another example is the gravitational force. Consequently, Gauss's flux theorem is not applicable to the divergence of the electric field.
Category: Classical Physics

[2] viXra:1912.0016 [pdf] submitted on 2019-12-02 05:50:40

Kareem's Radiation

Authors: Kareem Muhammad
Comments: 2 Pages.

derive the formula which calculate the radiation power of 1 mole of a sodium atoms due to the earth motion around sun
Category: Classical Physics

[1] viXra:1912.0006 [pdf] submitted on 2019-12-01 02:27:47

Power Transmission Via Wire Antennas Inside Metal Case

Authors: Xiaodong Liu, Qichang Liang, Yu Liang
Comments: 5 Pages.

A power transfer system is designed with wire antennas inside a metal case. There are two wire antennas namely transmitter and receiver. The metal case is connected to the ground and it serves as a third electrode between transmitter and receiver. The metal case also shields the radiation from antennas to outer space. The reflected impedance to the transmitter is reduced due to the interference with the metal case.
Category: Classical Physics