Lost Torsion Technologies of the USSR

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Table of content:

1. Introduction
2. Brief Overview of Torsion Fields
3. Torsion Field Detector
4. Simple Torsion Field Generator
5. Professional Torsion Field Generator
6. Conclusions

1. Introduction

I continue to introduce you to the lesser-known science
of bioenergetics and torsion radiation, which was discovered
by Soviet scientists as early as the 1980s. In this post,
I aim to summarize and systematize this knowledge, as well
as help you build the simplest devices for experiments with
torsion fields at home. There may be some errors or
inaccuracies, primarily due to the poor quality of scanned
original sources I received. In nature, there exists a special
type of radiation - torsion or twisting field. According to
the prevailing hypothesis, it permeates space and time, not
interacting with the familiar electromagnetic fields. It can
be generated by living organisms, such as humans. Torsion
fields are considered as physical carriers of information,
associated with the spin (quantum angular momentum) of
elementary particles. They form the basis of the Effect of
Transfer of Informational Action, enabling remote influence
through informational copies of objects (photographs,
portraits, spells, aura, etc.). Torsion fields do not obey
the inverse-square law and do not weaken with distance.

2. Brief Overview of Torsion Fields

How can we detect what cannot be seen or measured with
conventional instruments? It turns out that a simple system
of two electrodes immersed in ordinary distilled water can
be used. The secret lies in the phenomenon known as the
double electric layer - an ultra-thin charge layer that
spontaneously forms at the boundary between the metal
electrode and the liquid. To make such a system a sensitive
detector, it must be asymmetric. In other words, the
conditions around the two electrodes should differ in some
way. If the same radiation acts on two identical electrodes,
their reactions will cancel each other out, and we will
observe nothing. However, if we create an imbalance, the
system will respond to external influence by changing the
electric voltage or current between the electrodes. One of
the most stable, simple, and sensitive detector options was
proposed by Soviet scientist A.V. Bobrov. It is called a
"current" sensor and can be assembled easily at home. This
information is based on declassified documents: "Theses of
reports at the International Congress 'Bioenergoinformatics'
(BEI-98), Vol. 2, Barnaul, 1998, pp. 5-10."

3. Torsion Field Detector

How to build a torsion field detector?

Materials Needed:

- Small metal container (e.g., stainless steel)
- Piece of platinum or copper wire (second electrode)
- Distilled water
- Battery (1.5-4.5 V, e.g., 1-3 AA batteries)
- Microammeter for measuring small currents
- DC amplifier (or a highly sensitive multimeter)

Procedure:

- Fill the metal container with distilled water. The
container itself acts as the first electrode and as
shielding from interference.
- Immerse the platinum wire (second electrode) into
the water, with a shallow immersion (a few millimeters).
- Connect the circuit: connect the battery in series with
the microammeter and your electrodes (the "+" terminal
to the metal container, the "-" terminal to the platinum
wire). A small current (a few microamperes) will appear.
- The difference in material between the electrodes and
the applied current creates the necessary asymmetry
of the double electric layer. Your detector is ready!
- Place the system in a quiet location, away from
vibrations and electrical devices, to minimize noise.
- Observe the microammeter readings.
Research indicates that when a torsion radiation source
(e.g., a person focusing on generating a mental impulse)
is nearby, the current in the circuit should noticeably
change. Set the multimeter sensitivity to maximum
(2000 or 20000).
The double electric layers respond to external factors such
as acoustic and electromagnetic radiation, changing magnetic
fields, and high-penetration non-thermal radiation from
humans.

Protecting sensitive electrode systems from unwanted
influences is complex. To isolate the detector's response
to the studied factor, several precautions are recommended:

- Place sensors in a room with minimal temperature
fluctuations, away from electromagnetic and acoustic
interference sources.
- Keep the room free of people; ideally, only one experimenter
should be present.
- Limit the experimenter's presence to about 1 minute.
- Enclose sensors in a shielding chamber.
- Conduct synchronous registration of multiple independent
sensors.
- Record background current levels before and after exposure.
- Analyze results using standard statistical methods.

4. Simple Torsion Field Generator

How to build a simple torsion generator?

Materials Needed:

- A strong neodymium magnet (preferably pyramidal shape,
diameter 15-20 mm, or cylindrical, but preferably triangular,
diameter 10-15 mm)
- Copper wire (1-1.5 mm thick, about 50 cm long)
- Second wire of similar size, 30 cm long (for emitter)
- Base: small board, dense cardboard, or foam board (~10x10 cm)
- Tools: pliers or wire cutters, adhesive tape or hot glue

Assembly Steps:

Prepare the base: a small board to stabilize the device.
- Attach the magnet to the center of the base, securing
it with tape.
- Create an antenna: bend a 50 cm wire into a spiral
of about 4-5 cm diameter (like a snail shell), with
4-5 turns.
- Connect the spiral to the magnet: press one end of the
spiral wire firmly against the top of the magnet and fix
with tape or glue. If the magnet is ring-shaped, thread
the wire through the hole. The other end remains free.
- Make the emitter: bend a 30 cm wire into a circle of 3-4
cm diameter, leaving a small gap (5-10 mm).
- Connect the free end of the spiral to the emitter at any
point, securing with tape or twisting the wires together.
- Your simple torsion emitter is now assembled.

Testing the Device:

It creates a weak field detectable with the torsion detector
from beginning of the this article.

Experiments:

a) Water experiment: Place a glass of water on the emitter,
cover it, and leave for 2-3 hours. Use this water to water
plants or sprout seeds (e.g., cress). Compare with control
samples.
b) Pendulum experiment: Use a unmagnetized needle
or weight on a string as a pendulum. Move it slowly over
the emitter at various distances. Some report that the
pendulum behaves differently over the device.
c) Medical experiment: Apply the device to a painful area,
aiming the pyramid cone and antennas at the site. Leave
for 2-3 hours. Do not replace prescribed medical treatment;
this is experimental.

Note: This is a hobbyist-level torsion generator, likely not
powerful enough for stable informational or field effects.

5. Professional Torsion Field Generator

For those interested in creating more powerful, advanced
systems beyond laboratory experiments, consider these
principles:

Core with axiomatic matching: Use a pyramidal core made
of high-purity materials such as monocrystalline bismuth
or samarium-cobalt alloys, which have natural spin
polarization. The pyramid's proportions should follow
the golden ratio (? ? 1.618), with a vertex angle of exactly
63.43ø, ensuring resonance with background informational
torsion fields and enhancing spin coherence.

Bifilar winding and resonance modulation: The power
of the torsion field depends on precise resonance tuning,
not just current strength. Use a bifilar coil (two parallel
wires wound in opposite phases) powered by a highly
stable quartz oscillator in the 8-12 MHz range, where
the physical vacuum's permeability to spin disturbances
is increased.
Modulate the carrier frequency with encoded patterns
(e.g., sound spectra of healthy cells or mathematical
constants).

Synchronized phased arrays: For remote influence, create
a coherent torsion array from multiple emitters (minimum 7,
ideally 12, matching the vertices of an icosahedron).
Synchronize all emitters with a master generator to focus
the torsion beam at a distance. Use a parabolic reflector
coated with a thin aluminum hydride layer to polarize the
torsion waves further.

Safety Warning:
Working with high-power torsion fields requires deep
understanding and constant monitoring with calibrated
detectors (e.g., LCR meters tuned to measure phantom
inductance). Incorrect setup or phase desynchronization can
produce destructive standing waves, creating unpredictable
space-time anomalies near the device (appearance of ghosts
or UFOs). Do not exceed 15 W power output without proper
shielding.

6. Conclusions

Such stationary high-power systems were used in the USSR.
Torsion generators in the late 1980s were employed in
medicine by Professor G.N. Dulnev at LITMO. For example,
a "charged" torsion generator with a medicinal preparation
could induce biological reactions similar to taking the
actual drug, especially when combined with a donor
substance. In agriculture, remote processing of wheat crops
in Tajikistan (25,000 hectares) was achieved via stationary
emitters through satellites from the Moscow region,
increasing yields by 5.6 times on depleted soils without
fertilizers - confirmed by soil testing at Moscow State
University. In metallurgy, under the work of Academician
A.E. Akimov, torsion generators influenced molten metal
to modify its structure and properties intentionally.
Additionally, microgenerators capable of converting small
electrical powers into significant thermal flows were
developed. Overall, torsion technologies are a
long-forgotten but historically significant field of science
that developed in the USSR, later in Ukraine and Russia
during the 1990s. Unfortunately, none of the original
developers are with us anymore. Reproducing complex
laboratory experiments will be challenging, but perhaps
someone will find this topic intriguing and wish to further
develop this science.

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