UDC 53.02
Introduction
The Kirlian effect [1] was patented as a discovery in 1949 by Krasnodar inventor S.D. Kirlian together with his wife V.H. Kirlian. The discovery marked the beginning of research on photographing in the presence of high-frequency radiation. In the USSR, «kirlianography» was almost completely classified and no research was conducted, unlike in foreign countries. In 1939, S.D. Kirlian worked as an electrical equipment repairman at the city polyclinic. While repairing a physiotherapy machine that used high-frequency currents, he discovered a glow between the electrodes. He photographed this glow around the coin on a photographic plate.
Figure 1.A photo of a coin made according to the method of S.D. Kirlian.
Relevance
The role of «kirlianography», according to the author, has not yet been appreciated. It finds limited use in medicine for early diagnosis of diseases, for non-destructive testing of materials, in devices for visualizing magnetic relief, etc. Photographing bodies in a gas discharge offers great prospects for detecting their gravitational interaction with other bodies. By photographing one body in a gas discharge, it is possible to detect all the bodies with which this body gravitationally interacts.
Goals, objectives, materials and methods.
The purpose of this article is to prove that all interactions of bodies are produced by gravitational waves that are emitted by interacting bodies. The task is to prove that «kirlianography» occurs when, using an auxiliary heterodyne, gravitational waves of the gamma range emitted by bodies (target and photographic plates) during nuclear interactions are converted into gravitational waves of the light range, which are fixed on the photographic plate as electromagnetic radiation of the light range.
Figure 2 shows a block diagram of an installation for photographing objects in a gas discharge, applied by S.D. Kirlian [2].
The author believes that when defining the Kirlian effect as gas-discharge photography, an important circumstance is overlooked. The sum of the frequency of the visible spectrum (f c = 1015 Hz) and the frequency of the high-frequency pulse generator (f g = 108 Hz) is the frequency (f γ = 1023 Hz) of the gravitational interaction of the subject (6) and the measuring cell, or:
f γ — f g = f c ( 1 )
The signal from the gamma range, in which the object of the survey and the measuring cell interact with longitudinal gravitational waves, is transferred by longitudinal gravitational waves emitted by a heterodyne into the range of gravitational waves of visible light, the transverse component of which is an electromagnetic signal and is displayed in the photo layer of the measuring cell.
scheme
Figure 2. Classical single-electrode pseudomonopolar method of connecting a measuring cell to a high-frequency generator [2 p.134].
With the help of a gas discharge, it is possible to photograph a person’s hand (Fig. 3)
Figure 3. Photograph of a human hand made in a gas discharge.
The intensity and color of the pattern depend on the force of pressing the hand against the photographic plate, which changes the gravitational interaction by tidal accelerations. The gravitational wave channels connecting the hand and the photographic plate become shorter when pressed, and the signal will pass into the invisible ultraviolet region. By changing the frequency of the heterodyne, you can return the image to the visible area, but the image will change, reflecting the increased strength of the interaction.
The force of compression is compensated by the force of repulsion by gravitational waves. As the distance between the finger and the photographic plate decreases, gamma rays of higher frequencies interact, which cannot be completely overcome by human forces. With simple pressing, it is impossible to reach the distances of nuclear interactions. It is possible to overcome the distance of nuclear interactions using particle bombardment at accelerators.
It is known that photographs taken in a gas discharge make it possible to find flaws in wildlife (Fig. 4).
Figure 4. Different glow of a tomato just cut and after a while.
The author believes that the difference in the glow of only a sliced tomato and after a while is explained by the fact that in only a sliced tomato there is a movement of juices, which creates a rotation of particles and this rotation enhances tidal acceleration, depending on the speed of rotation. In a tomato photographed in a gas discharge some time after cutting, the movement of juices decreases, and tidal accelerations from particle rotation decrease. All that remains is the gamma radiation peculiar to inanimate nature.
The strength of gravitational waves emitted by physical bodies strongly depends on the presence of nuclei in them. Especially strong gravitational waves are emitted by physical bodies with nuclei in which thermonuclear reactions of various types take place.
Gravitational waves can be classified according to their sources:
gravitational waves emanating from physical bodies during their internal nuclear interactions;
gravitational waves emanating from physical bodies with an inner core;
gravitational waves emanating from physical bodies with an inner core in which thermonuclear reactions take place.
An asteroid of large size may not have a core and interacts with surrounding bodies only by internal nuclear interactions, the range of which is very limited. Therefore, the landing and retention of space stations on the surface of asteroids is hampered by the weakness of their gravitational interaction. The lack of rotation reduces the force of gravity inside the asteroid and reduces the strength of the emitted gravitational waves.
The source [3 p. 120] describes the effect of solar eclipses and other astronomical phenomena on gas-discharge imaging (GDV) devices. The author believes that the Kirlian effect is a gas-discharge visualization of gravitational waves. The same thing happens when visualizing magnetic lines of force (actually gravitational waves) with iron filings.
Conclusions
All interactions of bodies are produced by gravitational waves that are emitted by interacting bodies. «Kirlianography» occurs when, using an auxiliary heterodyne, gravitational waves of the gamma range emitted by bodies (the target and the photographic plate) during nuclear interactions are converted into gravitational waves of the light range, which are fixed on the photographic plate as electromagnetic radiation of the light range.
The author believes that the Kirlian effect is a gas-discharge visualization of gravitational waves.
Photographing bodies in a gas discharge offers great prospects for detecting their gravitational interaction with other bodies. By photographing one body in a gas discharge, it is possible to detect all the bodies with which this body gravitationally interacts.
The author believes that by selecting the frequency of the heterodyne and the sensitivity of the measuring cell, it is possible to detect not only the first wave, but also other waves from body interactions.
Bibliographic list:
1. The Kirlian effect. The Great discovery of a forgotten inventor, Science and Magic, [Electronic resource]. URL access mode: https://dzen.ru/a/XY_BSDIzVAC0s1kL ?ysclid=md8aovwkk6950201297, (Accessed 07/22/2025);
2. Shustov M.A., Protasevich E.T. Theory and practice of gas discharge photography. Tomsk: Tomsk Publishing House. Polytechnic University. University, 2001 – 252 p.
3. Korotkov K.G., Shustov M.A. The Kirlian effect – the past and the present. – St. Petersburg-Tomsk, 2017. – 144 p .