Initial Prerequisites for the Action of Torsion Radiation on Molten Metals
Introduction
The study of torsion field effects on physical matter represents one of the most rigorous and methodologically demanding frontiers of modern experimental physics. The experiments described here focus specifically on the effect of torsion radiation on metal melts — a phenomenon that, if reproducible and verifiable, carries significant implications for materials science and our fundamental understanding of physical vacuum states.
The central challenge of such research is methodological: how does one conclusively demonstrate that an observed effect is caused specifically by torsion radiation, and not by any conventional physical factor — electromagnetic, acoustic, electrostatic, or magnetic? The experimental protocol described below was designed precisely to meet this challenge.
1. The Torsion Generator and Its Physical Properties
In all experiments studying the effect of torsion fields on metal melts, torsion generators were used in which the rotation of an electromagnetic field served as the mechanism for generating the torsion field. The generators were housed in all-metal casings, which were grounded throughout all experiments.
This design served two purposes simultaneously: it shielded against any possible electromagnetic wave radiation from the generator’s internal components, and it guaranteed the absence of static charges on the generator casing — thereby eliminating any electrostatic field as a potential interfering factor.
2. Metrological Verification: Ruling Out Conventional Physical Factors
To ensure the experimental purity of the results, a comprehensive program of independent metrological verification was conducted before any conclusions were drawn. Special measures were implemented to exclude the influence of all known non-torsional physical factors.
2.1 Electromagnetic Radiation
A commission of metrology experts from NPO Krasnaya Zarya (Leningrad) carried out a full metrological inspection of the torsion generator. The result was unambiguous: the generator produces no measurable electromagnetic radiation in the frequency range up to 40.0 GHz — within the full sensitivity range of the metrological instruments employed.
2.2 Constant Magnetic Field
Special measurements conducted by the Research Institute of Metrology in Leningrad established that, at distances of 23 cm and greater from the generator, the constant magnetic field of the torsion generator falls below the level of the natural geomagnetic background.
To provide an additional margin of safety, the torsion generator was positioned at a minimum distance of 40 cm from the Tamman furnace and from any object of influence in all experiments. This distance ensured that the constant magnetic field of the generator could not have produced any measurable effect on the experimental results.
2.3 Acoustic and Ultrasonic Radiation
A dedicated test established that the torsion generator produced no acoustic radiation of any kind. This was a particularly important verification, as researchers from the Institute of Steel in Moscow had previously established that ultrasonic treatment can produce amorphization effects in metal melts. The possibility that the observed amorphization in these experiments might be attributable to ultrasonic action was therefore explicitly and conclusively ruled out.
2.4 Power Considerations
It should also be noted that all of these special verification measures were, in a strict sense, precautionary rather than strictly necessary. The torsion generator operated with a power consumption of only 10 mW. Even if — hypothetically — the generator had produced electromagnetic, acoustic, or ultrasonic radiation at this power level, the intensity would have been far too low to cause any significant physical effect in a metal melt. Similar considerations apply to all other conventional physical factors examined.
The known physical effects could not, by any reasonable physical argument, have been the cause of the observed phenomena.
3. Identifying the Torsion Nature of the Effect
Ruling out conventional physical factors was necessary but not sufficient. The critical remaining question was: how could one positively confirm that the observed effects were specifically the result of torsion action, and not of some other — perhaps also unknown — form of physical radiation?
This problem was resolved through a conceptually elegant experimental approach based on the fundamental physical properties of torsion fields.
3.1 Theoretical Basis: Torsion Screens
The torsion field is understood as a special state of the physical vacuum characterized by spin transverse polarization. By analogy with electromagnetism — where crossed electric or magnetic fields can create screening effects — it was theorized that two plates of a diamagnetic material, with mutually orthogonally ordered spins, would create crossed torsion fields capable of acting as a gate or screen for an external torsion field source.
Specifically, it was predicted that such a screen, placed between the torsion generator and the experimental object, would block the transmission of the torsion field while remaining transparent to all other known forms of physical influence.
3.2 Development of the Torsion Screen
A technique for the spin polarization of materials was developed for this purpose. The practical implementation used a pair of polyethylene films with mutually crossed spin orientation. This paired film system — the torsion screen — possessed the following combination of physical properties:
- Optically transparent — transmits visible light without attenuation
- Radiotransparent — transmits electromagnetic radiation across the radio frequency spectrum
- Acoustically transparent — transmits sound and ultrasound without barrier
- Magnetically transparent — does not shield static or alternating magnetic fields
- Gravitationally transparent — presents no barrier to gravitational influence
In other words, the torsion screen was transparent to every known category of physical interaction — with the sole exception of the torsion field itself.
3.3 Experimental Confirmation
The torsion screen was placed between the torsion generator and the experimental object. The result was decisive: all effects of torsion action on the objects ceased to be observed — across a large number of heterogeneous experiments conducted under varying conditions.
This result constitutes the critical proof. If the observed effects had been produced by any conventional physical factor — electromagnetic, acoustic, magnetic, electrostatic, or otherwise — a screen that is transparent to all such factors would have had no effect whatsoever on the experimental outcome. The fact that the screen completely suppressed the observed effects confirms unambiguously that those effects were torsion in nature.
The torsion screen thus served a dual role: as a practical shielding device, and as a physical identifier of torsion field action — a tool for definitively distinguishing torsion effects from all other physical influences.
Conclusion
The experimental protocol described here establishes a rigorous methodological foundation for the study of torsion field effects on metal melts. Through independent metrological verification by two specialized research institutions, the influence of all known conventional physical factors — electromagnetic radiation, constant magnetic fields, electrostatic fields, acoustic and ultrasonic radiation — was conclusively excluded.
The positive identification of the torsion nature of the observed effects was achieved through the development and application of a physically unique torsion screen: a spin-polarized polyethylene film pair that is transparent to all conventional physical interactions while selectively blocking torsion field transmission. The consistent suppression of all observed effects upon introduction of this screen across a large and diverse set of experiments provides compelling evidence that the phenomena under investigation are genuine torsion field effects — representing a class of physical interaction not accounted for by conventional electromagnetic or mechanical models.