Tonnel - No 30 - 2008

Magazine Overview

Title: ТОННЕЛЬ (TUNNEL)
Issue: No. 39 (2008)
Publisher: Academy of Informational and Applied Ufology / International Ufological Association
Content: A collection of scientific papers focusing on energy-information exchange (ENIO) phenomena, torsion fields, and related concepts.

Research into Energy-Information Exchange Phenomena: Experimental Results

This article, authored by G.N. Dulnev and A.P. Ipatov, summarizes results from ENIO research conducted between 1995-1998 at the Center for Energy-Information Technologies at the St. Petersburg State Institute of Precision Mechanics and Optics (TsEIT GITMO). G.N. Dulnev, director of the center, and A.P. Ipatov, head of the laboratory, are credited as key figures. The research is broadly divided into two groups: studies involving psychics and studies using a 'torsion field generator'. The authors note a convergence in understanding between the 'biofield' of psychics and the theoretically derived 'torsion field'. The article acknowledges the contributions of TsEIT employees and students, including Galina Mikhailovna Fedorova, Stanislav Vladimirovich Salangin, and Kirill Alexandrovich Razgulyaev.

Torsion Fields

The article provides a brief theoretical background on torsion fields, positing them as a fifth fundamental interaction beyond the four known in standard physics (electromagnetic, gravitational, strong, and weak). The concept of torsion fields has a history of over 100 years in theoretical physics. The development of this theory is traced from the geometric insights of Lobachevsky and Riemann, through Einstein's theory of relativity which links space, time, and matter, to the work of Élie Cartan and Roger Penrose. G.I. Shipov is highlighted for his work in the 1980s, developing equations for the physical vacuum using a ten-dimensional space-time model, effectively creating a unified field theory where all phenomena are described by the geometry of space.

Seven Levels of Reality

According to G.I. Shipov's theory, reality is structured into seven levels. Beyond the four classical states of matter (solid, liquid, gas, plasma) and the concept of the physical vacuum, Shipov introduces two additional levels: 'Absolute Nothingness' and the 'Primary Torsion Field (field of consciousness)'. The physical vacuum is described as a state of minimal energy devoid of elementary particles but containing fields, whose properties are inferred through indirect measurements and confirmed by experiment. The theory suggests that the 'Absolute Nothingness' exists in ordered and disordered states. The transition from disorder to order, or the 'renumeration of space points', is attributed to a 'primary superconsciousness'. The 'primary torsion field' is conceptualized as a twisted thread, where the twist is preserved even as the thickness approaches zero. This field is characterized by its ability to store and transfer information without energy expenditure, and its structures can have right (R) or left (L) twists, enabling binary coding. The interaction of torsion fields differs from electromagnetic interactions, with similarly directed twists attracting and oppositely directed twists repelling.

Torsion Generators

The article explains that torsion fields are generated by any form of rotation. Torsion generators are devices that create an electromagnetic field with specific parameters, which then generates a torsion field. The electromagnetic component is shielded, allowing the torsion field to pass through. The described generator, provided by MNTs VENT, operates on 90-180 V DC with modulation up to 1-5 V and 1 MHz, and can have right or left polarization. It has a cone-shaped directional pattern and dimensions of approximately 10x10x20 cm.

Measurement Stand

Most experiments in the publication utilize the 'ENIOTRON-2' measurement stand, developed by A.P. Ipatov. This stand is based on an analog-to-digital converter (ADC) integrated into an IBM PC, connected to an external amplifier-commutator unit. The stand supports up to 16 channels with amplification and 4 channels without. It offers various frequency ranges and voltage/mV scales with high resolution. Noise levels are minimized through grounding and software filtering. The 'ENIOTRON-2' software allows for multiple independent experimental methods, real-time processing, and automated operation. Key advantages include increased speed (from 1 Hz to 20 kHz), flexibility in sensor configuration, compatibility with MatLab for data analysis, and robust shielding against traditional fields like electromagnetism. A significant feature is its autonomous operation mode, which is crucial because the observer's presence can influence ENIO experiments, as detailed on page 38.

Research Conducted with Psychic Participation

Massive investigations are conducted with individuals ('operators') who wish to test their psychic abilities. These experiments often involve the operator influencing another person or technical devices (sensors). Common tests include identifying images or geometric shapes in envelopes, Zener card tests, and computer-based psychological assessments.

ENIO Research Between Operators

This section details a methodology for studying ENIO between individuals. An 'inductor' (operator) and a 'percipient' are placed in separate rooms. Each subject is accompanied by an experimenter, positioned so they cannot see the computer screen, to prevent bias. The experimenters communicate via a local computer network to coordinate the experiment. Other participants and observers are in a third room, monitoring the computer exchange. This setup allows for minimal influence from experimenters on the operators and enables discreet communication and control of the experiment, even without the operators' awareness of the ongoing discussions.

Recurring Themes and Editorial Stance

The recurring themes in this issue revolve around the exploration of phenomena beyond conventional physics, particularly focusing on energy-information exchange and torsion fields. The journal appears to advocate for the validity and scientific investigation of these unconventional concepts, presenting theoretical frameworks and experimental evidence. The editorial stance supports the idea that consciousness and information play fundamental roles in the universe, challenging the purely materialistic view of reality. The emphasis on experimental verification, even with unconventional methods like using psychics, suggests a commitment to empirical investigation within this specialized field.

This issue of "Nauka i Tekhnika" (Science and Technology) from November 1998, titled "11", delves into the scientific investigation of parapsychological phenomena, with a particular emphasis on telepathy and the influence of psychic abilities on technical devices. The magazine presents research conducted by professors G.N. Dulnev and B.L. Muratova, along with subsequent studies and experiments.

Registration of Psi Phenomena Using Technical Sensors

The core of the issue revolves around a methodology developed to register psi phenomena, specifically focusing on the transfer of information between individuals and the impact of operators on sensitive equipment. The research posits that telepathic communication or other forms of information transfer not explained by classical physics can be accompanied by changes in physiological functions, such as thermal flux in the forehead area.

Thermal and Physiological Monitoring

Initially, professors Dulnev and Muratova proposed using technical sensors to detect local thermal flux. The idea was that telepathic communication might alter physiological parameters like heart rate, brain rhythms, or temperature, which could be technically registered. Thermal flux was found to be a sensitive indicator of external influences. Experiments involved attaching thermal sensors and thermocouples to the foreheads of both the 'inductor' (sender) and 'percipient' (receiver), who were in separate rooms to eliminate conventional communication channels. Data on thermal flux and temperature were recorded over three phases: a baseline (background registration), the period of active influence (extra-sensory diagnosis or treatment), and a post-influence phase.

Mathematical Modeling and Statistical Analysis

To quantify the results, mathematical formulas were introduced to calculate coefficients of heat transfer and relative changes in parameters. The parameters $b_u$ and $b_p$ characterize changes in external conditions and sensor parameters relative to the background, while $\Omega$ assesses the effectiveness of the inductor's influence on the percipient. The study involved 17 inductors and 21 percipients, with results categorized into three groups based on the ratio of their parameter changes.

For assessing the success of information transfer, a statistical methodology based on the Bernoulli scheme was developed. This method calculates the probability of achieving a certain number of successful outcomes (e.g., correctly identifying a transmitted color) in a series of trials. The issue provides detailed examples of calculating these probabilities and defining criteria for distinguishing between random chance, unsatisfactory results, and successful outcomes. For instance, in an experiment involving the transmission of two colors, the probability of specific outcomes was calculated, and a threshold was established to determine if the results were beyond random chance.

Experiments and Findings

Several experimental examples are presented:

• Experiment №1: Involved transmitting and receiving images of red and blue colors. Out of eight attempts, seven were successful, leading to a conclusion of reliable information transfer with a 97% probability.
• Experiment №2: Focused on transmitting and receiving red and blue colors six times. Four out of six attempts were successful. The analysis indicated that outcomes 2, 3, and 4 were within the range of random chance (78% probability). While the results were not definitively conclusive due to fatigue, the experiment suggested a potential for information transfer.
• Experiment №3: Involved transmitting and receiving red and green colors seven times. Four out of seven attempts were successful. Outcomes 3 and 4 were considered within the range of random chance (54% probability), and the transfer of images was not definitively recorded.

Influence of Psychics on Technical Sensors

Beyond direct information transfer between individuals, the issue explores how operators (psychics) influence technical sensors. Three characteristic modes of influence were identified:

1. 'Charging' an object: Imbuing an object with some form of 'energetic substance'.
2. Creating a continuous 'energetic flow': Similar to an electric current.
3. An 'energetic strike': A rapid, powerful electromagnetic impulse.

These terms are presented as metaphorical, not directly related to established physics.

Types of Sensors and Their Responses

• Thermal Sensors: These sensors, like the "Teplomer Gerashchenko," responded to 'energetic flow' by showing a change in signal amplitude. However, they showed a weak response to 'charging' and were often indistinguishable from thermal noise. 'Energetic strikes' could also be registered, sometimes accompanied by artifacts from the operator's gestures, necessitating the use of protective casings.
• Magnetic Sensors: Standard magnetic induction sensors (e.g., G-79) were used. These sensors, designed to measure magnetic flux, were found to react to impulse-like influences. Research suggested they might also register fields of unknown physical origin. These sensors were less responsive to 'charging' and 'flow' but reacted to 'energetic strikes'. A notable experiment involved an operator influencing a magnetic sensor from 15 km away, though potential interference from external noise made definitive conclusions difficult.
• Optical Testers: An optical tester (OMK3-76-B) initially showed promise but was later deemed unreliable due to instability, especially when used with a torsion generator. Results from this device were questioned.
• Gas-Discharge Sensors (Kirlian effect): These sensors have slow response times and are unsuitable for detecting 'energetic strikes'. They are sensitive to 'charging' and 'energetic flow' in direct contact but less effective for remote influence. Their main drawbacks are instability and poor reproducibility, leading to their exclusion from further research.

The 'Dirt' Effect and Operator Strategies

An interesting phenomenon observed during the diagnosis of material objects (e.g., images in envelopes) was the 'dirt' effect. If an operator incorrectly identified an object (e.g., calling a square a circle), subsequent operators might perceive both the correct object and the incorrect one. This is hypothesized to be due to the operator 'charging' the object during diagnosis.

The issue highlights that operators often use the method of mentally visualizing the object of influence ('воздействие по образу'), which proved particularly effective, especially when dealing with distance or shielding.

Statistical Analysis of Operator Performance

Results from a cycle of testing graduates of a healing course (A. Ignatenko) are presented. These tests involved four methods of influencing technical sensors and four methods of diagnosing material objects. Operator performance was rated on a five-point scale. The results indicated that operators could be broadly categorized: approximately 55-60% excelled at diagnosis, 35-40% at influence, and only 5-10% were proficient in both. A small percentage (2-3%) of operators consistently produced results far exceeding the average, often individuals with established reputations.

Conclusions

The research presented in this issue concludes that:

• Information transfer between people via an unknown medium exists.
• This transfer is typically accompanied by changes in physiological functions (e.g., thermal flux in the forehead), which depend on the individual's state and vary with experience. Even under identical experimental conditions, results can differ slightly, consistent with the variability of physiological indicators.
• The effectiveness of experiments involving operators influencing sensors (especially magnetic ones) increases when psychics employ the 'воздействие по образу' (influence by image) method.

Recurring Themes and Editorial Stance

The magazine consistently explores the intersection of science and the unexplained, focusing on empirical research and the development of methodologies to study phenomena that challenge conventional scientific understanding. The editorial stance appears to be one of open inquiry into parapsychology, bioenergetics, and related fields, utilizing scientific instruments and statistical analysis to validate and quantify these often-elusive effects. There is a clear effort to present these investigations within a scientific framework, even when dealing with concepts that are not fully understood by current scientific paradigms.

This issue, identified by the number 21, focuses on research into the effects of a torsion generator on blood. The primary date indicated is October 1996, suggesting the research was conducted around that time. The content is in Russian and appears to be a scientific or technical publication.

Research on the Effects of a Torsion Generator on Blood

The issue details two series of experiments conducted in October 1996 to investigate the impact of a torsion generator (TG) on blood parameters. The first series focused on standard clinical blood analysis indicators, including hemoglobin, erythrocytes, leukocytes, neutrophils (segmented and band forms), eosinophils, lymphocytes, and monocytes, as well as the erythrocyte sedimentation rate (ESR).

The second series specifically utilized ESR as the most sensitive indicator to study the properties of the torsion fields generated. The research involved exposing blood samples from two volunteers to the TG in a cyclical manner. Each cycle consisted of drawing blood, exposing it to the TG (except for a control cycle), and then performing a clinical blood analysis. Five cycles were conducted in total, with the first serving as a control without TG exposure. Subsequent cycles involved varying the TG's operational modes, including left and right polarization and different power supply voltages.

Blood Analysis Results

Table 3 presents the changes in blood parameters before and after exposure to the torsion field. The data indicates that while some parameters showed minor fluctuations, the ESR exhibited more significant changes. The study noted that the changes in most blood parameters were within the margin of error for the measurement methods. However, the ESR was found to be highly sensitive, with values changing considerably depending on the TG's radiation parameters (e.g., power supply voltage). The data for the two patients is presented separately, with the first patient's data in regular font and the second's in italics.

Investigation of Fields Using ESR

Further research focused on the fields generated by the experimental apparatus, including the TG, power supply, modulator, and computer. The objective was to determine if the TG emitted a field of unknown origin or if the observed effects were due to electromagnetic fields generated during the experiment. If an unknown field was detected, the aim was to characterize it. ESR was used as the criterion for evaluating the impact.

The experimental setup involved different rooms (A, B, and C) for blood sampling, exposure, and analysis. The experiments were conducted in cycles, with blood samples exposed to the TG and then ESR measured. The duration of exposure varied, with some cycles involving 5-minute exposures and others longer durations.

#### Cycle 1: Baseline ESR Measurements

This cycle aimed to establish baseline ESR values in different experimental rooms. With all electrical equipment off in rooms A and C, and only a computer on in room B, the baseline ESR values ranged from 4 to 8 mm/h. The study concluded that the computer's operation had no significant influence on the ESR.

#### Cycle 2: Influence of Auxiliary Devices

This cycle investigated the effect of auxiliary devices (power supply and modulator) on ESR. With the TG turned off, the auxiliary devices were activated. Blood samples placed at 20 cm and 300 cm from the TG were exposed to the fields generated by these devices. The results showed that the auxiliary devices influenced the ESR, with values reaching 15 mm/h at both distances. This indicated that the distance from the devices did not affect the outcome.

#### Cycle 3: Extended Exposure to Auxiliary Devices

This cycle examined the impact of prolonged operation (15 minutes) of the auxiliary devices. After the devices warmed up, blood samples were exposed for 5 minutes. The ESR values increased to 35 mm/h at both 20 cm and 300 cm. The conclusion was that the auxiliary devices significantly affected ESR, and this effect increased over time, possibly due to the devices being lamp-based. The researchers noted the need to eliminate this influence for further TG experiments.

#### Cycle 4: Influence of the Power Supply

This cycle specifically tested the effect of the power supply on ESR. After 35 minutes of the auxiliary devices being on, the power supply was turned off, while the modulator remained active. Blood samples were exposed to the modulator's field. The ESR values dropped slightly to 33 mm/h, suggesting that the power supply's operation did not significantly impact ESR.

#### Cycles 5 & 6: Influence of the Modulator

These cycles investigated the modulator's effect. The modulator operated for 40 minutes and was then turned off. Blood samples were exposed at 10 and 40 minutes after the modulator was switched off. The ESR values remained consistently at 8 mm/h, indicating that the modulator had a substantial influence on ESR, which did not exhibit an aftereffect. Due to this significant influence, the researchers decided to replace the existing power supply and modulator with a new semiconductor-based device.

#### Cycles 7-9: New Power Source for TG

These cycles tested a new semiconductor-based power source for the TG. Experiments were conducted in room C. The results showed that the new power source did not affect the ESR, with values remaining at 7 mm/h before, immediately after, and 10 minutes after activation.

#### Cycles 10 & 11: Short-Term TG Exposure

These cycles examined the effect of short-term (30 seconds) exposure to the TG. Blood samples were placed 15 cm from the TG. The ESR increased from 6 mm/h (before exposure) to 10 mm/h after 30 seconds of exposure. This suggested that even brief TG exposure could alter ESR, and longer exposure times warranted further investigation.

#### Cycle 12: Distance Dependence of TG Influence

This cycle studied the dependence of TG influence on distance. Blood samples were exposed to the TG for 5 minutes at distances of 15 cm, 35 cm, and 50 cm. The ESR values were 20 mm/h, 40 mm/h, and 30 mm/h, respectively. This non-linear relationship between distance and ESR indicated that the TG's influence varied significantly with proximity.

#### Cycles 13-16: Investigating the 'Aftereffect'

These cycles aimed to determine the presence and duration of the torsion field's 'aftereffect'. The TG was activated for 5 minutes, and then blood samples were introduced into room C at different time intervals (immediately, 7, 15, and 25 minutes) after the TG was turned off. The ESR values showed a significant increase, reaching 25 mm/h, 30 mm/h, 7 mm/h, and 7 mm/h at these intervals, respectively. The study concluded that an 'aftereffect' was indeed observed and could not be explained by electromagnetic fields, suggesting the presence of an unknown component in the TG's radiation. The 'phantom' effect's duration was estimated to be 12-15 minutes after a 5-minute TG operation.

#### Cycle 17: Long-Term Aftereffect

This cycle investigated the aftereffect after a longer TG operation (15 minutes). After 55 minutes from the TG's shutdown, blood samples were taken. One sample was placed in room B (where the TG was located) and another in room A (control). After 5 minutes, ESR was measured. The sample in room B showed an ESR of 12 mm/h, while the control sample in room A remained at 4 mm/h. This indicated that the aftereffect persisted for over an hour following a 15-minute TG operation.

General Conclusions

The overall conclusions drawn from the research are:

1. The ESR is a suitable indicator for registering and evaluating the properties of TG radiation.
2. The TG creates a field that alters ESR (ranging from 8 to 40 mm/h) and has a period of aftereffect. The duration of this aftereffect depends on the TG's operational time (approximately 15 minutes after 5 minutes of operation, and over 1 hour after 15 minutes of operation).
3. Besides the torsion field, auxiliary devices also influence ESR. The lamp-based modulator significantly affected ESR (8 to 35 mm/h), but this influence did not exhibit an aftereffect.
4. The observed aftereffect suggests the presence of fields of an unknown nature.
5. The TG radiation exhibits non-linear intensity with distance. For example, at 15 cm, ESR was 20 mm/h; at 35 cm, it was 40 mm/h; and at 50 cm, it was 30 mm/h.
6. The increase in ESR up to 35-40 mm/h suggests a potentially unfavorable effect of the torsion field on the human organism, although this is a speculative conclusion based on in vitro experiments.

Investigation of Torsion Generator Radiation Using Technical Sensors

This section discusses the challenges in evaluating experimental data related to torsion fields due to the lack of established criteria for assessing their effectiveness. The researchers differentiate between 'registration of the torsion generator's effect' (detecting a signal) and 'registration of the torsion field' (implying information transfer via the torsion field itself).

Special Screen for Torsion Field Identification

A special screen made of highly ordered linear polyethylene was developed based on torsion field theory. This screen acts as a polarizing filter. If its presence between the generator and the sensor alters the signal, it suggests the involvement of a torsion field, as electromagnetic fields are not absorbed by polyethylene.

Magnetic Sensor

An idea to use a magnetic sensor, which had shown good results in detecting human fields, was explored. Initial experiments without electromagnetic shielding yielded no positive results. To mitigate electromagnetic interference, the sensor was placed inside a steel tube (11 mm wall thickness). This improved results, reducing noise by an order of magnitude, but significant pulsed interference remained. These pulses, often exceeding 500 nT, could cause the instrument to 'peg out' and were difficult to shield effectively. Sources of interference included lighting, welding equipment, and thunderstorms.

Without shielding, magnetic field fluctuations ranged from 70 to 200 nT, with variations of 20-50 nT during experiments. Shielding reduced these fluctuations significantly. The researchers observed two types of responses from the magnetic sensor to the TG: pulsed bursts upon activation/deactivation/polarity switching, and long-term changes in signal amplitude. Sometimes both responses occurred in a single experiment.

Figure 8 illustrates the response of the magnetic sensor to the activation of the torsion generator, showing a significant peak upon activation followed by a gradual decrease. The text notes that attributing these pulsed bursts solely to electromagnetic phenomena is not always possible, as their reproducibility is only about 20%, which is atypical for electromagnetic fields. The signal was often stronger at the beginning of a work session (multiple experiments in a day) than at the end.

Protocol of Experiment No. 4

This section details a specific successful experiment conducted on April 18, 1995. The experiment used a G-79 magnetometer with a range of 0.1 µT, placed in a 30 cm long steel tube (11 mm wall thickness). The TG and the shielded sensor were mounted on an optical bench 50 cm apart. The TG's power supply was 150 V, and its modulation frequency was 300 kHz with a 5 V amplitude. The data sampling rate was 0.12 seconds.

The experiment involved several steps:

• Start (0 seconds): Data acquisition begins, recording background noise.
• 110 seconds: TG is activated with left polarization. The signal amplitude increases.
• 320 seconds: Polarization is switched to right. The signal amplitude drops to background levels. Subsequent changes might be due to background field variations or 'aftereffects' of the torsion field.
• 560 seconds: A polyethylene screen (for torsion fields) is installed. This action also changes the signal amplitude.
• 890 seconds: The screen is removed, again causing a signal change.
• 1010 seconds: The TG is switched off, resulting in a signal change.
• 1180 seconds: Data acquisition stops, ending the experiment.

Reproducibility and Limitations

The study notes that while a significant number of experiments (10 out of 70) showed a detectable signal from the TG, their reproducibility was low (20-30%). Experiments with the polyethylene screen indicated that it only reliably shielded the experimental curve in about 50% of cases. The pulsed bursts observed were initially thought to be due to sparking contacts in the switch, but with the use of electronic switches, they still occur, albeit less frequently, possibly related to capacitor charging processes.

Recurring Themes and Editorial Stance

The recurring theme throughout this issue is the investigation of 'torsion fields' and their effects, particularly on biological systems (blood) and through technical sensors. The research highlights the sensitivity of ESR to these fields and the puzzling phenomenon of 'aftereffects,' suggesting the existence of unknown physical components beyond standard electromagnetic interactions. The editorial stance appears to be one of rigorous, albeit challenging, scientific inquiry into phenomena that defy conventional explanations, emphasizing the need for new detection methods and criteria for evaluating results in this nascent field of study. The publication seems dedicated to exploring and documenting experiments related to torsion physics and its potential applications or implications.

This issue of the magazine, identified by the number '31' on page 31, focuses on experimental investigations into the detection of torsion fields. The content is primarily in Russian and details the setup, execution, and analysis of experiments using various sensing devices.

Magnetic Sensor Experiments

Page 31 presents a graph (Figure 9) showing the registration of torsion radiation using a magnetic sensor. The graph illustrates changes in the signal amplitude, noted to be around 1-1.5 nT. The text suggests that leftward field effects increase the signal amplitude, while rightward effects decrease it. The ability to register a response when a torsion field screen was applied and removed indicates the successful detection of a torsion field. The conclusion is that the magnetic sensor reliably registered the effect of the torsion generator (TG), confirming the presence of a torsion field. However, the text also notes that the magnetic sensor requires careful shielding from interference, particularly impulse-type noise, which was not fully achieved in these experiments.

Optical Tester Experiments

Pages 31-32 introduce an optical tester (OMK3-76-B) as a potential sensor for energy-informational effects. Figure 10 illustrates the setup of this optical tester, which includes a semiconductor laser diode, a quartz fiber optic cable, and a germanium photodetector. Preliminary experiments with this device, conducted without the torsion generator (background or 'fon' measurements), revealed a significant and irreproducible scatter in the initial states of the sensor. The authors concluded that this device is not suitable for detecting constant or slowly changing signals and therefore abandoned its use for registering UENIO (unidentified anomalous phenomena) events.

Thermal Sensor Experiments (Gerashchenko Thermometer)

Pages 32-38 detail experiments using thermal sensors, specifically the Gerashchenko thermometer, referred to as 'thermal cup' (teplomer Gerashchenko). Figures 11 and 12 illustrate the 'background' states of the optical tester and the construction of the Gerashchenko thermometer, respectively. The thermal sensor is described as a thermocouple made of constantan wire with a copper coating, designed to produce a thermoelectric EMF proportional to temperature differences.

'Thermal Cup' Designs

Two main designs are discussed: 'Thermal Cup No. 1' (used for years in laboratory experiments) and newer versions, 'Thermal Cup No. 2' and 'Thermal Cup No. 3' (Figure 13). These cups incorporate a heater, a thermal field equalizing pad, and the Gerashchenko thermometer. 'Thermal Cup No. 2' uses one thermometer, while 'No. 3' uses two.

Experimental Procedure and Results

Experiments involved activating a heater to stabilize the thermal flow through the thermometer, then exposing the stabilized sensor to a torsion generator. Changes in the signal during TG exposure were expected to indicate registration of the torsion field, as other thermal parameters were stabilized.

A series of 40 experiments was conducted in spring 1996. In 37 of these, no signs of TG influence were detected. However, in three experiments, the measurements suggested a possible influence. Protocols for two of these experiments are presented.

Figure 14 shows results from an experiment on March 19, 1996, where the TG was placed 1 cm from the sensor. The graph of thermal flow shows fluctuations that might be attributed to the TG, but the authors state it's not definitively provable.

Another experiment on March 22, 1996, also showed potential effects, but the results were not conclusive.

Page 37 presents results from an experiment with 'Thermal Cup No. 2' (Figure 15), showing the thermal flow and autocorrelation functions before, during, and after TG exposure. The upper graph suggests an increase in oscillation period during TG exposure. Correlation analysis, using methods described by Pirsole and Bendat, was applied to objectively confirm differences between background and TG exposure signals. The analysis indicated a distinction between the signals, but it remained unclear if the torsion field itself was the cause.

Identified Deficiencies and Improvements

Several reasons for unsatisfactory results were identified:
1. Influence of air and thermal currents, particularly from the experimenter.
2. The physical model of the Gerashchenko thermometer, with a response time of about five seconds, was too slow for rapidly changing signals.

To address these issues, improvements were made:
1. Automation of TG activation/deactivation using an electronic key controlled by a computer.
2. Abandoning the conversion of voltage readings to thermal flow values, thus bypassing the limitation of the thermometer's response speed.

Additionally, the correlation methodology was adopted for all experiments. 'Thermal Cup No. 3' with two thermometers was developed to allow for the isolation and filtering of common noise.

Further Experiments and Findings

In October-November 1996, a large series of 132 experiments was conducted. In 13 (10%) of these, a statistically significant effect of the TG was recorded, and in another 8 (6%), a possible effect was observed. The remaining experiments were unsuccessful.

Page 39 highlights a significant finding: the influence of the observer (experimenter) on the results. It was observed that when the experimenter was actively monitoring the equipment, fewer positive results were obtained. When the experimenter was less involved or absent, the number of successful experiments increased. This phenomenon was attributed to the potential extrasensory abilities of the operator influencing the sensors.

These methodological improvements led to a substantial increase in the effectiveness of TG registration, reaching up to 10% positive results. However, further enhancements were deemed necessary.

A key drawback was the erasure of raw data after processing, preventing re-analysis with different methods. The data acquisition and processing procedures were separated to allow for independent analysis of the same dataset. A trial series of four experiments using this new approach yielded positive results, confirmed by spectral analysis.

Spectral analysis indicated that the observed effect was possibly due to an electromagnetic nature, potentially caused by the TG's housing not being grounded. This was rectified by modifying the TG's internal construction and grounding the housing. A subsequent control experiment showed a significant reduction in the amplitude of the modulation frequency harmonic.

Experimental Protocols and Data Analysis

Pages 40 presents experimental protocols and graphical data (Figure 16) from an experiment (N5/3) conducted on October 26, 1996. This experiment involved two thermal sensors and recorded dispersion and entropy over time, with the TG applied from the 100th to 150th mark. The data acquisition rate was 0.5 ms, with 250,000 data points.

The text on page 40 discusses the challenges of processing large datasets in the non-automated approach, noting that processing one experiment could take 12-15 hours. The need for automation was evident, especially with kilohertz sampling rates and 15-20 minute experiment durations, generating millions of data points. A 'windowing' method, inspired by computer memory addressing, was developed for processing data in parts.

Recurring Themes and Editorial Stance

The recurring themes in this issue revolve around the experimental investigation of torsion fields and the development of sensitive detection apparatus. The magazine appears to adopt a stance of rigorous scientific inquiry, detailing experimental setups, methodologies, data analysis, and the challenges encountered. There is a clear emphasis on improving experimental precision and reliability, addressing sources of error, and validating findings through objective analysis. The inclusion of findings related to experimenter influence suggests an openness to exploring less conventional aspects of scientific observation.

This issue, identified by page number 41, delves into the methodology and experimental findings related to the study of torsion fields (TG). The primary focus is on a data processing technique known as the 'window method' and its application in distinguishing torsion field effects from other phenomena, particularly electromagnetic interference.

The Window Method

The 'window method' is explained as a technique for analyzing data streams. It involves segmenting the data into 'windows' of a specific length (N) and calculating various functions, such as dispersion and informational entropy, for each window. The position of these windows can be shifted by a 'step' (D), which is often equal to the window length. The parameters N and D are chosen by the researcher to optimize the analysis. The document notes that typically, optimal parameters yield between 1000-4000 output data points, with window lengths of 1000 or 1024 being common. The method is versatile and can be adapted to compute different functions available in systems like MatLab. The formula for Shannon entropy is provided: I = -Σ Wᵢ log₂ Wᵢ, where Wᵢ is the probability of the i-th state.

Dispersion is highlighted as a preferred method due to its algorithmic simplicity and was used in most experiments. Data acquisition occurred on a computer at the measurement stand, with data transferred via a local network for processing, which could be done in real-time or post-experiment. The system allows for re-processing archived data with different methods.

Experimental results are typically presented as graphs, with the x-axis representing the window number (or time) and the y-axis showing the calculated function value. Experiments were conducted using a temporal scheme of 'background interval, impact interval, after-effect interval'.

Experimental Design and Results

The results of experiments are often summarized by three average values: Zf (background), Zв (impact), and Zπ (after-effect). A key metric introduced is the 'impact criterion k', calculated as k=(Zв-Zf)/(Zπ-Zf), which serves as an integral assessment of the experiment's outcome, though it has limitations.

To determine the method's error margin, a series of 20 'dummy' experiments were performed to capture background noise. The resulting variation in criterion k was found to be 5%, which was adopted as the method's error.

A pilot study in December 1996 involved 25 experiments applying the window method to TG impact on a thermal cup. In 60% of these, the impact criterion reliably exceeded the error margin. After re-processing data a year later with improved 50Hz frequency filtering algorithms, an additional three experiments (totaling over 70%) showed a reliable impact criterion.

Case Studies

• Figure 18: An experiment on January 10, 1998, with a 'L' type field (20 Hz, 110 V, 90 cm) showed clear changes in dispersion for two sensors during the impact phase (marks 300-600). The impact was reliably registered by both sensors.
• Figure 19: An experiment on January 9, 1998, with an 'R' type field (100 Hz, 60 V, 90 cm) also showed similar changes in dispersion for two sensors. The impact was reliably registered only by the upper sensor, making the experiment successful.
• Figure 20: Another experiment on January 9, 1998, with an 'R' type field (1000 Hz, 60 V, 90 cm) showed dispersion changes for a single sensor during the impact phase.

Observations on Field Polarization

Comparing results across experiments revealed a connection between the changes in averaged function values and the polarization type of the TG field. With left-type polarization, the changes during impact and cessation of impact had different signs (k>0). With right-type polarization, the changes had the same sign (k<0), a phenomenon that is difficult to explain but consistently observed in successful experiments.

Further Investigations and Conclusions

Subsequent experiments aimed to clarify the nature of the detected signal. A series of 25 experiments were conducted under conditions identical to a previous series, yielding a 93-95% match in the impact criterion values. This high reproducibility, while expected in classical physics, raised questions about whether the detected signal was truly torsionary or electromagnetic, given the initial low success rate in detecting TG effects.

To address this, 10 experiments were performed under the most unstable TG operating conditions. The results showed high reproducibility (over 90%), leading to two possibilities: either the signal was indeed electromagnetic, or the understanding of TG reproducibility was flawed.

Another series of 5 experiments aimed to answer the question, 'What does the torsion generator emit?'. In this series, conditions from the January 10, 1998 experiment were replicated, showing reliable TG impact detection. Subsequently, a 30x30 cm polyethylene screen, designed to block torsion fields, was placed between the TG and the thermal cup. In both cases where the screen was used, the sensor did not register any impact. This led to the conclusion that the thermal cup detects torsion fields, not electromagnetic radiation, as polyethylene does not block electromagnetic waves in this frequency range.

Further confirmation involved three experiments where the TG's electronic components were active, but the torsion field emitter was turned off. This manipulation completely eliminated the TG impact on the thermal sensor, reinforcing the conclusion that the detected signal was from the torsion field.

Arguments For and Against Torsion Field Detection

Arguments For:
1. No impact was observed when using a polyethylene screen or disconnecting the TG emitter.
2. Observed dependencies of the impact criterion on distance and TG supply voltage are easily explained by torsion field theory, not electromagnetic theory.
3. The dependence of the impact criterion's sign on the TG polarization type is difficult to explain from an electromagnetic perspective.
4. The absence of TG radiation detection in 25-30% of experiments is uncharacteristic of electromagnetic field experiments.

Arguments Against:
1. The absence of a 'residual effect' (after-effect), which was clearly observed in experiments with ESR (erythrocyte sedimentation rate), was not found in these studies.
2. The clearly observed harmonic at the TG modulation frequency in the spectrum suggests an electromagnetic nature of the TG impact.

Recurring Themes and Editorial Stance

The issue emphasizes the emerging field of 'energo-informational exchange' and posits that the phenomena studied are new and cannot be explained by existing fundamental interactions. A recurring theme is the significant role of the 'human factor' and the observer in these experiments. The research highlights the challenges of achieving high reproducibility and distinguishing torsion signals from electromagnetic ones. The editorial stance appears to favor the existence and detection of torsion fields, based on the experimental evidence presented, while acknowledging the need for further research to definitively prove their nature and mechanism.

The document concludes by summarizing key findings: the likely existence of torsion fields as information carriers, the effectiveness of the 'window method' combined with 50 Hz filtering for data processing, the non-linear characteristics of TG intensity, and the potential influence of the observer. It also raises concerns about the safety of TG generators in certain operating modes. The bibliography lists numerous related publications, primarily in Russian, focusing on parapsychology, information exchange, and torsion fields.

This document is the table of contents for a publication titled 'ОГЛАВЛЕНИЕ' (Table of Contents), issue number 51, from the year 1998. The publisher is identified as 'СПб гос. ин-т точной механики и оптики' (St. Petersburg State Institute of Precision Mechanics and Optics). The primary language is Russian.

Key Articles and Themes

The table of contents reveals a focus on 'Torsion Fields' and the 'Physical Vacuum.' The publication delves into the history and theoretical underpinnings of torsion fields, including their connection to spin and gravity, and their potential manifestations. It also explores the concept of the physical vacuum as a fundamental, material medium, rather than empty space, composed of elementary vacuum particles (EVPs).

Introduction to Torsion Fields

The introductory sections cover the basics of torsion fields, their history, and the concept of seven levels of reality. It also introduces torsion generators and their potential effects.

Measurement and Experiments

Several sections are dedicated to experimental investigations involving torsion fields, including studies with psychics, research on the effects of torsion fields on technical sensors, and the impact of torsion generators on blood analysis (e.g., ESR). Investigations using technical sensors like magnetic and optical testers are also listed.

The Physical Vacuum

A significant portion of the content is dedicated to the physical vacuum. It discusses the 'mysticism of emptiness' and presents the 'Theory of Fundamental Field' (TFP) by I.L. Gerlovina. This theory proposes that the physical vacuum is a dense, material environment made up of elementary vacuum particles (EVPs), which are formed from the merging of particle-antiparticle pairs. The theory suggests that the vacuum is the basis of all reality and that it is responsible for the formation of all physical structures.

Quantum Mechanics and TFP

The publication contrasts the TFP with traditional quantum mechanics, suggesting that TFP offers explanations for quantum phenomena that are currently considered 'unexplainable' or 'mysterious.' It addresses the behavior of electrons in atoms and the concept of wave-particle duality.

Light and Fundamental Constants

An article titled 'What is Light?' explores the nature of light within the framework of TFP, suggesting it is not a stream of photons but rather 'droplets of light' from the physical vacuum. The theory also claims to explain the physical basis for the speed of light limit.

Triunity of Space-Time-Matter

A key contribution highlighted is the discovery and proof of the 'law of triunity of space-time – matter.' This concept emphasizes the inseparable connection and interdependence of space, time, and matter.

Practical Applications and Future Prospects

The publication suggests that TFP has practical implications, including predicting new phenomena like the influence of atomic nuclei on mineral formation and the possibility of synthesizing new elements. It also mentions the recent discovery of high-temperature superconductivity and suggests that TFP can provide the necessary theoretical framework for further advancements in this area.

Authors and Source

The authors are identified as Gennady Nikolaevich Dulnev and Alexey Petrovich Ipatov, with contact information provided. The source is cited as 'СПб гос. ин-т точной механики и оптики' (St. Petersburg State Institute of Precision Mechanics and Optics), published in 'author's edition' in 1998.

Recurring Themes and Editorial Stance

The recurring themes are the exploration of alternative physics theories, particularly torsion fields and the physical vacuum, challenging established scientific paradigms. The editorial stance appears to be in favor of these unconventional theories, presenting them as capable of solving fundamental problems in physics and offering a new understanding of the universe, with potential for significant practical applications. There is an underlying critique of mainstream physics for its limitations and perceived inability to explain certain phenomena.

This issue, dated March 2003, is a collection of scientific papers from the 2nd International Scientific-Practical Conference "Informoenergetika 3rd Millennium: Sociological-Synergetic and Medico-Ecological Approaches." The primary focus is on the exploration of torsion fields and their potential applications, particularly in information transmission and energy generation. The conference was organized by Informoenergetika and held in Ukraine.

Torsion Connection — A New Physical Basis for Information Transmission Systems

This article, authored by A.E. Akimov, V.Ya. Tarasenko, and S.Yu. Tolmachev, introduces torsion fields as a novel physical foundation for information transmission systems. It posits that existing radio and telecommunication systems face limitations due to overloaded frequency bands and signal absorption. The authors suggest that torsion fields, unlike electromagnetic fields, can overcome these obstacles.

The article explains that torsion fields are theorized to be generated by spin or rotation, and are intrinsically linked to the physical vacuum. It draws parallels with the Einstein-Cartan theory, which considers the torsion of spacetime. The authors highlight that while electromagnetic fields are generated by charges, torsion fields are generated by spin or angular momentum. They also note that torsion fields can be self-generating and can arise from geometric or topological configurations.

Key properties of torsion fields discussed include their axial symmetry, their ability to pass through matter without loss, and their non-energetic, superluminal information transfer capabilities. The concept of "torsions" as quanta of torsion fields is introduced, with a suggestion that they might be low-energy neutrinos.

The article contrasts torsion fields with electromagnetic and gravitational fields, noting that torsion fields create fields with axial symmetry, whereas the others have central symmetry. It also points out that like charges repel and unlike charges attract in electromagnetic fields, but in torsion fields, like spins attract and unlike spins repel.

The Unusual Properties of Torsion Fields

This section delves into the unique characteristics of torsion fields, emphasizing that they are an objective reality confirmed by experiments. It suggests that understanding these properties can lead to specific applications. One example given is the potential to control inertia, which is proposed to be a manifestation of torsion fields in mechanics. This could lead to the development of universal propulsion systems that do not rely on reactive thrust or friction.

The text introduces "torsion mechanics," which is based on Ricci geometry (geometry of torsion) rather than Euclidean geometry. This new mechanics is presented as necessary for describing systems with rotation, analogous to how relativity is needed for near-light-speed objects.

Significant attention is given to experimental research and applications of torsion fields since the early 1980s. This includes investigations into the effects of torsion fields on various substances, particularly metal alloys. Torsion technologies have been developed for producing alloys with improved grain structure and altered crystal lattices. The production of silumin (an aluminum-silicon alloy) using torsion technology is highlighted, noting its advantages over standard methods, such as increased strength and plasticity without the need for traditional alloying additives.

Torsion Technologies and Energy Generation

This part of the document discusses the application of torsion technologies in energy generation, particularly in the context of the global energy crisis. It presents two main viewpoints on obtaining energy from the physical vacuum: one that considers it impossible due to the vacuum's minimal energy, and another that posits the vacuum's infinite energy potential.

The authors lean towards the latter, citing the work of physicists who suggest that the non-interacting oscillators of the physical vacuum possess infinite energy. They reference J.A. Wheeler's estimate of the energy density of vacuum fluctuations as a lower bound. The possibility of obtaining energy from the physical vacuum is presented as a theoretical avenue for addressing energy needs, though the practical implementation remains a challenge.

The concept of "efficiency coefficient" (as opposed to "coefficient of useful action" or КПД) is introduced for open systems that can draw energy from external sources. The text mentions various types of installations (electrostatic, magnetic, electromagnetic, and thermal) that claim efficiencies exceeding 100%, with some patents reporting up to 3000% efficiency. However, it notes that independent expert evaluations often do not confirm these high figures, possibly due to proprietary knowledge or technological limitations.

A specific example discussed is the "torsion vortex generator" (TVG), a thermal installation that reportedly achieves efficiencies over 100%. The mechanism is explained as the interaction of the installation's torsion field with the spin clusters of the physical vacuum, leading to an increase in water temperature. The TVG is described as having two energy sources: electricity for the motor and energy from the physical vacuum for heating.

Torsion Technologies in Medicine and Diagnostics

This section focuses on the application of torsion fields in medical and biological research. It highlights studies on the effects of static torsion fields and wave torsion emissions on living organisms at various levels. The development of highly sensitive quantum systems for registering torsion emissions has enabled the creation of databases of torsion emission spectra from different tissues and diseases.

The "Torsion Diagnostics System" (TORDI) is presented as a tool for diagnosing human health by measuring characteristic torsion frequencies of cell groups. This system is based on the principle that cells are primary sources of torsion spectra. The TORDI system is described as a commercial installation with potential for further development.

The authors emphasize that the application of torsion technologies is not limited to the discussed areas and extends to various sectors, including industry, agriculture, and everyday life. They suggest that these technologies herald the "noosphere era" and have the potential to solve global systemic crises.

Literature

The issue includes an extensive list of references, citing works by prominent scientists such as E. Cartan, A. Einstein, G.I. Shipov, N.A. Kozyrev, and others, covering topics from classical physics to modern theories of vacuum and torsion fields.

Author and Source Information

The issue identifies A.E. Akimov as the author, detailing his academic and professional affiliations. The source is stated as materials from the 2nd International Scientific-Practical Conference "Informoenergetika 3rd Millennium: Sociological-Synergetic and Medico-Ecological Approaches," held in Ukraine on March 21-22, 2003. A URL for further information is also provided.

Recurring Themes and Editorial Stance

The recurring themes in this issue are the fundamental nature of torsion fields, their unique properties, and their potential to revolutionize various scientific and technological domains, particularly energy generation and information transmission. The editorial stance appears to be one of strong advocacy for the exploration and application of torsion technologies, presenting them as a paradigm shift capable of addressing major global challenges, including the energy crisis and systemic societal issues. There is a clear emphasis on the theoretical underpinnings of torsion fields, supported by experimental evidence and the development of practical devices.

This issue of "Nauka i Tekhnika" (Science and Technology), issue number 7, delves deeply into the complex and often counter-intuitive realm of torsion fields. The articles explore their theoretical underpinnings, experimental investigations, and potential applications, particularly in communication.

Theoretical Frameworks of Torsion Fields The issue begins by tracing the historical development of torsion field theory, noting how early approaches, such as those based on Einstein-Cartan theory, suggested that torsion effects were too weak to be observed. The work of Kopchinsky and Trautman in the early 1970s, which linked spacetime torsion to the elimination of cosmological singularities, initially reinforced this view. However, later research by Hel, Kibble, and Schima indicated that the Einstein-Cartan theory did not encompass all aspects of torsion fields.

Subsequent theoretical work, particularly concerning theories with dynamic torsion, revealed that the Lagrangians for such fields could include numerous terms with constants not dependent on fundamental constants like G (gravitational constant) or h (Planck's constant). Crucially, these theories did not mandate that torsion effects must be very small, thus opening the door for experimental verification.

The concept of the physical vacuum (PV) is central to understanding torsion fields. The PV is described as a complex quantum dynamic object exhibiting fluctuations. While standard approaches rely on concepts from Weinberg, Salam, and Glashow, the text revisits Dirac's electron-positron model of the PV. This model views the PV as a system of nested, counter-rotating wave packets of electrons and positrons, termed 'fitons'. These fitons, when their spins are opposite, are self-compensating in terms of charge, spin, and magnetic moment.

• Different types of PV polarization states are proposed, corresponding to different fields:
• E-field (Electromagnetic): Arises from charge polarization of the PV due to a charge 'q'. This is linked to phenomena like the Lamb shift.
• G-field (Gravitational): Hypothesized to arise from mass 'm' causing symmetrical oscillations of fiton elements along the axis of the perturbing object.
• S-field (Spin/Torsional): Generated by a classical spin 'S'. If the spin of a fiton aligns with the source spin, it maintains its orientation; if opposite, it inverts. This leads to transverse spin polarization of the PV, interpreted as a spin (torsional) field.

These EGS (Electromagnetic, Gravitational, Spin) polarized states of the PV are presented as universal fields, or 'first-class fields' in Utiyama's terminology, observable at both macro and micro levels. The issue emphasizes that the PV itself is the fundamental entity, and its various polarization states manifest as different fields.

Properties of Torsion Fields The issue enumerates several key properties of torsion fields and waves: 1. Source: Torsion fields are generated by classical spin or macroscopic rotation. They can also arise from spacetime torsion, PV perturbation, or as a component of electromagnetic fields. 2. Quanta: The quanta of torsion fields are proposed to be 'tordions', possibly low-energy neutrinos. 3. Interaction: Torsion fields interact with the spin states of objects, potentially altering nuclear or atomic spin orientations. 4. Symmetry: Torsion fields possess axial symmetry relative to their source. 5. Polarization: Torsion fields can be axial or radial, and each can be right- or left-polarized. 6. Charge Analogy: Similar to electric charges, like torsion charges (spins) attract, while unlike torsion charges repel. 7. Dynamic Generation: Stationary spinning objects create static torsion fields. Dynamic spinning objects, exhibiting imbalances like changes in angular frequency or precession, generate wave-like torsion radiation. 8. Range: Static torsion fields have a finite range ('near zone'), while wave-like torsion radiation is not limited by distance. 9. Medium: The physical vacuum (PV) acts as the medium for torsion wave propagation, behaving like a holographic medium. This explains the informational, non-energy-transferring, and potentially superluminal nature of these signals. 10. Potential: The potential of torsion fields is zero, indicating their non-energetic character. 11. Interaction Constants: The constant for static spin-torsion interactions (Cartan torsion) is estimated to be less than 10^-50, making observable effects unlikely. For dynamic torsion (Cartan torsion) and torsion fields with Ricci or Weitzenböck torsion, there are no theoretical limits on interaction constants. For torsion fields arising from electromagnetic fields (electro-torsion interactions), the constant is on the order of 10^-3 to 10^-4. 12. Comparison to EM: Electro-torsion interaction constants are slightly weaker than electromagnetic interaction constants, suggesting that under certain conditions, torsion effects could cause observable changes. 13. Penetration: Torsion fields pass through natural media without attenuation, a property attributed to their neutrino quanta. This allows for communication through dense materials. 14. Speed: Torsion wave speed is theoretically infinite, a concept supported by theories of tachyons and spontaneous symmetry breaking. This property has been experimentally observed in phenomena unrelated to torsion fields. 15. Ubiquity: All bodies, living and non-living, possess non-zero atomic and/or nuclear spins, leading to magnetic moments. Interactions with Earth's magnetic field cause precession, generating wave-like torsion radiation. Thus, all bodies emit their own characteristic torsion fields. 16. Individuality: Due to variations in atomic composition, chemical bonding, and spatial arrangement, each body has a unique torsion field signature.

Applications in Communication The properties of torsion fields make them highly suitable for communication systems: * Distance Independence: No energy expenditure is needed to compensate for signal loss due to distance. * No Absorption: Natural media do not absorb torsion waves, eliminating the need for energy compensation typical in radio communication. * Information Transfer: Torsion waves transmit information, not energy, acting on a torsion receiver. * Non-Local Transfer: Propagation through the PV's holographic structure allows for non-local, potentially instantaneous communication. * No Repeaters: The non-local nature eliminates the need for signal repeaters.

These characteristics suggest that torsion fields are ideal carriers for information transfer, communication, television, navigation, and localization.

Experimental Research The issue highlights experimental efforts to verify the existence and properties of torsion fields. A key experiment involved transmitting binary signals over a 22 km distance in Moscow using a torsion transmitter and a bioelectronic system as a receiver. The bioelectronic system's ability to change tissue conductivity based on the torsion field's polarization was utilized. The experiment successfully transmitted signals without errors to a specific receiver, demonstrating the feasibility of torsion-based communication and the high penetration capability of torsion waves.

Recurring Themes and Editorial Stance The recurring theme throughout this issue is the exploration of torsion fields as a fundamental, yet largely unrecognized, aspect of physics. The editorial stance appears to be one of advocating for the serious consideration and investigation of torsion phenomena, moving beyond historical skepticism. The articles emphasize the potential of torsion fields to revolutionize communication and our understanding of the physical vacuum, presenting them as a unified field from which other forces and particles emerge. The underlying message is that the physical vacuum, and its various polarization states (E, G, S fields), is the true fundamental entity in nature.

Title: Электросвязь (Electrosvyaz)
Issue: 5
Date: 2001
Language: Russian

This issue of "Electrosvyaz" from 2001 delves into the cutting-edge research and experimental findings related to torsion signals and their potential applications in communication, as well as exploring fundamental concepts in theoretical physics, particularly concerning the nature of the vacuum and matter.

Torsion Signal Transmission and Reception

The issue details the experimental verification of torsion signal transmission, drawing parallels to early radio communication pioneers like A.S. Popov and G. Marconi. It highlights the successful demonstration of transmitting information via torsion signals over distances, even through absorbing media, with minimal power consumption (30 mW). This capability is presented as a revolutionary step in information transfer.

The development of torsion signal receivers is a significant focus. The article describes various technical approaches, including those developed independently by different researchers. A.V. Bobrov's receivers utilized double electrical layers (liquid-metal or semiconductor junctions) and employed correlation processing for signal analysis, achieving a high signal-to-noise ratio (S/N > 50). G.N. Dulnev's receivers used metal-metal junctions and fiber-optic systems, experimentally establishing the effect of spin saturation in nonequilibrium media under torsion field influence. E.G. Bondarenko's receivers employed film-based converters and externally excited devices. The article also references early work by N.M. Myshkin and T. Ieronymus in the registration of torsion radiation, noting that a lack of understanding of the physical nature of these emissions limited their contemporaries' assessment of these findings.

Since 1986, experiments have largely utilized a standardized torsion transmitter, described as having dimensions of 500x500x400 mm and weighing 4.5 kg. This transmitter allows for tuning the carrier frequency, adjusting output signal intensity, and operating with any modulation type. The integration of torsion communication with radio and wired communication is seen as aligning with the ideology of R. Sibser's seven-level communication protocol.

Research Context and Support

Research in torsion communication is being conducted under the program "Torsion Communication," managed by the International Institute of Theoretical and Applied Physics of the Russian Academy of Natural Sciences and the Intersectoral Scientific and Technical Center for Venture Nontraditional Technologies (MNTЦ ВЕНТ). A cooperative network of organizations is involved. Experimental prototypes of torsion communication transceivers have been developed as a base for various applications, including information transfer, telemetry, control, navigation, and location.

Prior to 1985, torsion communication research was primarily initiative-driven. Further progress (until 1988) was facilitated by support from the KGB USSR and the Council of Ministers USSR. The first torsion radiation generators were developed around 1980, with patent priority established on March 29, 1990. The first public reports on torsion communication occurred at conferences in 1995, coinciding with the centenary of radio invention. The article asserts Russia's absolute and undisputed priority in this field, noting the absence of published results elsewhere by 1995 and in 2001.

If preliminary experiments confirming low noise levels in torsion channels are validated, the realization of torsion communication channels with exceptionally high throughput is anticipated, potentially enabling the transmission of entire two-dimensional images. The authors suggest that current understanding and technical capabilities in torsion communication have surpassed those of Popov and Marconi in radio communication a century ago, though much remains to be done. They predict that within two years, many torsion communication tasks could be resolved using existing technology, leveraging significant experimental experience and a substantial component base.

The authors foresee torsion communication systems for information transfer, telemetry, control, navigation, and location replacing similar radio-technical systems in the first half of the 21st century.

Physics of Vacuum and Microleptons

A separate article, "On the Microlepton Nature of Relic Radiation" by L.I. Kholodov and I.V. Goryachev, explores fundamental physics concepts. It begins by referencing the inverse relationship between quantum energy and wavelength, noting the impossibility of a quantum with both minimal energy and minimal size, or maximal energy and maximal wavelength.

The work proposes a hierarchy of qualitatively different levels of matter, introducing a concept of local physical constants that vary with level. This hierarchy is linked to the structure of the physical vacuum. The authors suggest that the vacuum is not chaotic but rather an ordered state of matter, characterized by levels k=1, 2, 3... which represent super-light states of matter, including the physical vacuum itself.

The article discusses the concept of a "leptonic quadriga of Terletsky" (LQT) in the electromagnetic vacuum, defining its electrical and magnetic constants. It posits that the LQT is an electromagnetic cell of the vacuum, ensuring a consistent phase velocity for quanta of different frequencies. The work examines the hypothetical hierarchy of matter levels in the vacuum, allowing for transitions of particles between levels. It contrasts two scenarios for displaying quanta: one where frequency remains constant and another where energy remains constant.

Specifically, the energy of quanta decreases as they move to higher levels (k=1, 2, 3...) in the first scenario, while their mass remains constant in the second. The article presents a graphical representation of these levels and transitions. It suggests that level k=1 might define processes within atomic nuclei, while levels k=2 could correspond to free microparticles with mass characteristics matching this level.

The authors analyze the display of particles from level k=0 to level k=2, specifically for electron-positron annihilation into gamma quanta. They calculate the energy of these gamma quanta and relate it to a temperature of 16.9°K.

Further, the article discusses the registration of relic cosmic radiation by Penzias and Wilson in 1965, which indicated a temperature of 2.7°K. The authors propose that this radiation is not a result of the universe's evolution but rather an experimental manifestation of one of the vacuum's characteristic levels. They suggest that the particles of this level, termed "microleptons" by A.F. Okhatrin, are what is being observed. This interpretation reframes relic cosmic radiation as a consistent energetic and electromagnetic quantization of the vacuum.

Acknowledgements and References

The authors express gratitude to Yuri Petrovich Rybakov and Nikolai Vladimirovich Samsonenko for their contributions and support. The issue includes an extensive bibliography, citing numerous works on torsion fields, physics of vacuum, quantum mechanics, and related topics, along with a list of authors and their affiliations.

Recurring Themes and Editorial Stance

The recurring themes in this issue revolve around the exploration of unconventional physics, particularly torsion fields and their potential for advanced communication technologies. There is a strong emphasis on experimental validation and the assertion of Russian priority in these research areas. The issue also engages with fundamental questions about the nature of the vacuum, matter, and energy, proposing theoretical frameworks that challenge conventional physics paradigms. The editorial stance appears to be one of advocating for and promoting research in these non-traditional scientific domains, highlighting their potential to revolutionize both communication and our understanding of the universe.

This document, identified as page 91 of a publication, delves into theoretical physics, specifically focusing on the structure of the electromagnetic vacuum and its implications for particle physics and cosmology. The content is primarily in Russian and presents complex mathematical formulations and theoretical arguments.

Electromagnetic Structure of Vacuum and KTЛ

The text begins by discussing the characteristic impedance of the vacuum (Z₀) and its relation to fundamental constants (ε₀, μ₀, c), suggesting it points to the electromagnetic structure of the vacuum. It then introduces the concept of the Leptonic Quadriga of the Vacuum (KTЛ), which is proposed to be consistent with these electromagnetic constants. The laws of conservation within the KTЛ framework are listed, including the conservation of mass, energy, momentum, charge, and angular momentum.

Key equations are presented relating the energy of particle-antiparticle pairs (e⁺e⁻) to their electric dipole moment and the energy of magnetic dipoles (e⁻e⁻) to their magnetic dipole moment and inductance. The concept of electric and magnetic constants (ε₀ and μ₀) is extended to the KTЛ context, defining them as linear specific capacitance and inductance, respectively.

Quantum Mechanics and Vacuum Properties

The document explores the energy of a quantum (E = ħω) and its relation to the dipole length (pᵧ = el). It derives expressions for the dipole length and relates them to the fine-structure constant (α). The fine-structure constant is defined as the ratio of the positron dipole length to the wavelength of a quantum with energy W = E*.

The discussion then shifts to the phase velocity of electromagnetic signals in vacuum, stating that it is constant and independent of frequency, similar to lossless transmission lines. This leads to the conclusion that the KTЛ acts as an electromagnetic cell of the vacuum, facilitating the distortion-free propagation of signals at a constant phase velocity.

Hierarchical Model of Vacuum States

A significant portion of the document is dedicated to a hypothetical 'Hierarchy' of vacuum states, proposed by the authors. This hierarchy is characterized by qualitatively different levels of matter states, with local constants varying according to power-law sequences of the fine-structure constant (α). Specific relationships are given for electric charge (eₖ), magnetic charge (gₖ), Planck's constant (ħₖ), and energy (Eₖ) at different levels (k) of this hierarchy.

Two variants of energy and particle transitions within this hierarchy are considered: one where frequency (ω) is constant and another where energy (E) is constant. These variants lead to different behaviors of particle mass and energy as the level k changes.

Microleptons and Vacuum Structure

The text introduces the concept of 'microleptons' as potential analogues of elementary particles (e, p, n) existing at higher levels (k=1, 2, ...) of the 'Hierarchy'. These microleptons are suggested to be part of atoms and nuclei. The fine-structure constant is used to derive formulas for these microleptons.

Speed of Light and Vacuum Constants

The document examines the constancy of the speed of light (C) across different vacuum levels. It postulates that while the speed of light for direct motion (Cₚ) and rotational motion (C<0xE2><0x82><0x9B>) might differ at higher levels, they are equal at the base level (k=0). The issue arises that the vacuum's electromagnetic constants (ε₀, μ₀) might change with the hierarchy level, potentially affecting the speed of light. The authors propose that the speed of light for electromagnetic waves tends towards infinity at higher levels of the hierarchy.

Experimental Confirmation and Comparison of Models

The authors reference experiments by R. Avramenko and colleagues, which they claim provide experimental confirmation for their theoretical framework. A new constant, W<0xE2><0x82><0x96>в, is introduced, which is experimentally determined and theoretically matches the quantized energy of a gamma-quantum at the first level (k=1) of the proposed hierarchy.

The document then discusses R. Avramenko's concept of a 'natural background of electron Bose-condensate' (ФЭБК), which he believes constitutes over 90% of the universe's mass and explains phenomena like instantaneous interactions and the nature of neutrinos. The authors suggest that Terletsky's vacuum model could accommodate Avramenko's ideas.

A comparison is made between Avramenko's and Terletsky's vacuum models, highlighting similarities in their treatment of quantum energy additions, hidden mass, and instantaneous interactions. The table summarizes key differences and similarities, particularly concerning the quantization of fundamental constants and the mechanism of weak interactions.

Neutrino Nature and CPT Symmetry

The issue touches upon the nature of neutrinos and antineutrinos, suggesting that neutrinos might not exist as independent particles but rather transfer their properties to the vacuum during beta decay. The authors propose an extended CPT symmetry, termed T(CPT), to resolve apparent violations of symmetry laws when considering negative mass regions.

Beta Decay Model

A model of neutron beta decay is presented, illustrating how the KTЛ, with spin s=0, transforms into a Z-boson (spin s=1) that interacts with a d-quark, leading to the transformation of a neutron into a proton and the emission of an electron and an antineutrino. This model is depicted in Figure 7.

Recurring Themes and Editorial Stance

The recurring themes in this document are the fundamental structure of the vacuum, the quantization of physical properties at different energy levels, and the exploration of alternative models to standard physics. The authors advocate for a unified understanding of vacuum properties, drawing connections between quantum mechanics, electromagnetism, and cosmology. The editorial stance appears to be one of proposing and exploring novel theoretical frameworks that challenge conventional physics, supported by experimental claims and theoretical derivations.

This issue of "Сознание и физическая реальность" (Consciousness and Physical Reality), Volume 3, Issue 4, published in 1998, features several articles exploring theoretical physics, experimental biology, and materials science, with a particular focus on torsion fields and alternative cosmological models.

Theoretical Physics: Terletsky's Vacuum and the Origin of the Universe

The issue includes a significant theoretical paper by L.I. Kholodov and I.V. Goryachev titled "Considerations on the Nature of Relict Radiation in Terletsky's Vacuum." This article continues their exploration of a vacuum model proposed by Terletsky, characterized by positive and negative mass particles. They posit that quantizing this vacuum leads to a "Hierarchy of qualitatively different levels of matter states." At level k=4 of this hierarchy, photons with a temperature of approximately 2.7 K emerge, which they suggest could be the relic radiation from the Big Bang. The authors contrast this with the standard Big Bang model, which describes the universe expanding and cooling from an initial dense state, and also mention alternative stationary universe models, citing Yakov Petrovich Terletsky's hypothesis about the spontaneous generation of particle pairs with positive and negative mass from a vacuum. They introduce the concept of "Terletsky's vacuum" and the "Terletsky lepton quadrupole" (TLQ) as a fundamental structure composed of dipoles with electric and magnetic charges. The paper mathematically details the "Hierarchy" and how energy quanta (photons) might transition between levels, linking the 2.7 K temperature to the TLQ's energy at a specific level (k=4).

Experimental Biology: Torsion Fields and Biological Organisms

Another article, "The Effect of Torsion Field on Laboratory Mice" by V.F. Panov, B.V. Testov, and A.V. Klyuev, investigates the biological impact of torsion fields. The researchers used a torsion field generator and studied its effects on mice exposed to lethal doses of 137Cs radiation. Their findings suggest that static torsion fields of right polarization significantly improve the survival rate of irradiated mice, with increases ranging from 17-33% in some experimental variants. While the duration of life for surviving mice did not show significant differences, the right-polarized torsion field appeared to have a beneficial effect. The study also noted that left-polarized torsion fields did not produce similar results. Further experiments explored the thermal response of animals to torsion fields, observing an increase in heat production, suggesting a physiological reaction that could potentially be harnessed to improve the condition of weakened or sick organisms.

Materials Science: Torsion Fields in Metallurgy

An article by S.A. Kurapov and V.F. Panov, "Deep Field Effect on Molten Metals," details the application of a specialized torsion field generator in metallurgy. Developed at OAO "Motovilikha Plants," this generator, based on an electromagnetic principle, is capable of deep and volumetric influence on molten metals and solutions. The generator has been used to treat molten metal in quantities ranging from 160 kg to 60 tons. The results indicate that treating molten metal with this field can produce a finer structure and significantly reduce carbide precipitation in high-carbon steels, leading to an increase in impact toughness by up to 52%. The field's high penetration capability allows it to affect the melt through the walls of a metallurgical furnace.

Bibliography and Authors

The issue includes extensive bibliographies for each article, citing relevant scientific literature. Author biographies are provided, detailing their affiliations and academic credentials. For the article on Terletsky's vacuum, the authors are identified as L.I. Kholodov from FGPU KBOM named after V.P. Barmin and I.V. Goryachev from the Kurchatov Institute, IVTEM. The article on torsion fields and mice lists V.F. Panov (Professor at Perm State University), B.V. Testov, and A.V. Klyuev. The metallurgy article credits S.A. Kurapov (Head of the "Fractal" laboratory) and V.F. Panov (Project Scientific Supervisor). An article on the thermodynamic basis of organism reactions is authored by A.I. Zotin.

Recurring Themes and Editorial Stance

The recurring themes in this issue revolve around exploring phenomena that lie outside mainstream scientific consensus, particularly torsion fields and alternative cosmological models. The editorial stance appears to be open to investigating these unconventional areas, presenting both theoretical frameworks and experimental results that challenge established paradigms. The publication serves as a platform for researchers exploring fringe science, offering detailed technical explanations and experimental data to support their hypotheses.

This issue of "Nauka i Religiya" (Science and Religion), issue number 11 from 1999, published by the journal itself, is primarily in Russian and focuses on scientific research, particularly in the fields of physics, material science, and biology, with a significant exploration of parapsychological phenomena.

Research on Torsion Fields and Their Effects

The issue features several articles detailing experimental investigations into torsion fields. One section presents microscopic images (Photos 5-10) illustrating the effects of torsion fields on metal structures. Photo 5 shows a metal sample irradiated in mode №1, revealing fine austenite crystals and carbides at grain boundaries and within crystals, with a score of 4-4.5. Photo 6, from mode №2, displays larger austenite crystals and carbides as separate inclusions, not connected to grain boundaries, with a score of 1-1.5. Photo 7, from mode №3, shows fine austenite crystals with no carbide precipitation at grain boundaries, only rare inclusions, also scored 4-4.5. Photo 8 depicts the body of a pile-driving machine cast from cast iron, treated with a generator field, suggesting improved material properties. Photo 9 shows untreated cast iron, characterized by ledeburite, typical of white cast irons. Photo 10 shows cast iron treated with a field, resulting in gray cast iron with lamellar graphite, corresponding to grade Cч20.

The technology using these fields is presented as beneficial, allowing for:
1. Avoidance of heat treatment and homogenization costs.
2. Reduced melting time.
3. Decreased defect rates by improving steel's casting properties.
4. Production of simple steels with properties similar to alloyed ones.
5. Savings in electricity and gas.
6. Release of production space.
7. Reduction of production costs by up to 2 times in some cases.
8. Shortened production processes.
9. Increased product competitiveness.

The generator used in these experiments is described as being fully shielded from electromagnetic fields, producing a field of unknown nature with high penetrating ability. Patents have been secured for this technology, with further developments underway. The theoretical development of this field is considered highly relevant, enabling the technology for processing molten steels and non-ferrous metals.

Impact on Cell Biology

An article by V.P. Kaznacheev, L.L. Mikhailova, and A.N. Mosolov, titled "Research on the Effect of Torsion Fields on Cells," discusses the limitations of classical physics in explaining certain experimental facts and introduces the concept of torsion fields. The authors propose that the fabric of spacetime has a torsion basis. They present findings from laboratories indicating unknown informational flows in cells and organisms, possibly linked to torsion fields. Their experiments suggest that intercellular connections are not solely mediated by electromagnetic fields. The study investigated the effect of left- and right-rotating torsion fields on human kidney cell cultures. Results indicated that left-rotating fields led to increased mitosis, while right-rotating fields resulted in reduced mitosis but enhanced protein synthesis. Table 1 shows that left-rotating fields increased mitosis rates significantly compared to the control. Table 2 demonstrates that protein synthesis was significantly inhibited by left-rotating fields but activated by right-rotating fields.

Telekinesis and the Physical Vacuum

Another article, "Telekinesis at the Quantum Level. Superfluid Physical Vacuum" by L.B. Boldyreva and N.B. Sotina, explores phenomena not described by acoustic or electromagnetic fields, such as telekinesis. These effects are characterized by their independence from electromagnetic shielding and distance, and their selectivity. Experiments involving operators influencing flicker noise generators (MOS transistors, photodiodes, etc.) are detailed. These generators, shielded from external electromagnetic fields, showed sensitivity to psychic influences. The effects were observed as changes in the amplitude of low-frequency fluctuations, known as flicker noise (1/f-noise). The article posits that operator influence occurs at the quantum level, affecting the wave function of quantum objects. This leads to a hypothesis that the physical vacuum, modeled as a superfluid liquid of fermion pairs, plays a role. Experiments with flicker noise generators, shielded from electromagnetic influences, showed reactions not only to psychic influences but also to periodic changes in lunar phases. Analysis of six years of background noise data revealed a period of increased noise "flares" equal to half a synodic lunar month, a rhythm more pronounced than daily or solar activity rhythms.

Literature and Authors

The issue includes a list of references, citing patents and scientific publications related to torsion fields and their effects. It also provides author information, including V.F. Panov, a Doctor of Physical and Mathematical Sciences, and S.A. Kurapov, head of the "Fractal" laboratory at OAO "Motovilikha Plants."

Recurring Themes and Editorial Stance

The recurring themes in this issue revolve around the exploration of phenomena that lie beyond the scope of conventional physics, particularly focusing on torsion fields and their potential applications and implications. The journal appears to adopt an open stance towards investigating these unconventional areas, presenting experimental data and theoretical hypotheses that challenge established scientific paradigms. There is a clear emphasis on empirical research and the potential for new technologies derived from these investigations, while also acknowledging the need for further theoretical understanding and research into the fundamental nature of these fields and their interactions with matter and biological systems.

Title: Свет (Light)
Issue: №3
Date: 1999
Publisher: Not specified
Country: Russia
Language: Russian

This issue of "Svet" magazine features a prominent interview with Anatoly Evgenyevich Akimov, an academician and director of several research institutes, focusing on his work with torsion fields and their potential applications. The magazine also includes a list of cited scientific works and information about the authors.

Article: Akimov A.E.: The Universe's Engine?.. It Exists!

The main focus of this issue is an extensive interview with Anatoly Akimov, who is presented as a leading figure in theoretical and applied physics, particularly in the field of torsion technologies. Akimov has been researching torsion fields for over twenty years, describing them as the 'fifth force' of nature, present wherever there is rotation.

Torsion Fields and Energy Generation

Akimov asserts that torsion fields are inherent to the biofield of all objects and that their nature is analogous to electromagnetic fields, with different frequencies corresponding to different colors. He highlights a key difference: like torsion charges attract, while unlike charges repel. He explains that any geometric shape can disrupt the physical vacuum, creating a torsion field. In the mid-1980s, Akimov collaborated with the military to develop torsion apparatus. In 1986, his MNTZ "Vent" center reportedly transmitted binary information (sound and image) using torsion, claiming speeds billions of times faster than light, capable of reaching the Moon instantaneously.

He addresses the concept of torsion generators, stating they require no fuel and could revolutionize the world. Akimov claims that numerous installations exist with efficiencies ranging from 300% to 500%. He refutes the notion that energy cannot be extracted from the physical vacuum, arguing that the vacuum is not a system of minimal energy but a dynamic, 'boiling' liquid with infinite energy fluctuations, citing work by academicians Zel'dovich and Zimmer.

Practical Applications and Production

When asked about the widespread adoption of torsion technology, Akimov reveals that simplified versions have been used for heating cottages in the Moscow region. Larger units (50 kW and above) for heating homes and industrial buildings are being produced in limited quantities in Yaroslavl, requiring significant investment (500 million rubles) for mass production. He claims torsion generators are 1095 times more efficient than fuel-burning systems.

The article mentions the EHP-3 device, a 50 cm tube that heats a large house, reportedly developed by the military for submarines and operating on water ionization. Akimov suggests this is a different type of installation but also involves torsion processes, potentially leading to cold nuclear fusion reactions.

Scientific Debate and Criticism

Akimov discusses the controversy surrounding the "Urusvati" power station, which uses a rotating vortex. While acknowledging its operation based on torsion fields and interaction with the quantum vacuum, he disputes Vladimir Mashkov's explanation that gamma photons generated from proton and neutron decay are the source of its power. Akimov believes that cold nuclear fusion reactions are responsible.

He also addresses criticism from academicians V. Nakoryakov and A. Rebrov of Novosibirsk, who questioned the "Urusvati" station's principle based on the second law of thermodynamics. Akimov argues that their application of the law is too rigid and fails to account for the specific phenomena arising from spin effects in open systems.

Searle's Generator and UFOs

The interview draws a parallel between Akimov's generators and the experiments of English electrician Searle in 1950, who built a generator with rotating magnetized discs that reportedly levitated and flew. Searle claimed his generator lost weight and flew like a UFO at certain rotation speeds. Akimov suggests that Searle's device, a multi-layered roller bearing, might indeed replicate flying saucer technology based on torsion principles. He notes that French patents exist for flying saucer designs utilizing mechanical and electromagnetic processes or light/laser streams, but organizing such light vortices remains a mystery.

The Philadelphia Experiment and Psychotronics

Akimov expresses skepticism about the Philadelphia Experiment, where the USS Eldridge allegedly became invisible using torsion generators. He believes the event may not have happened as described, citing the strict secrecy protocols in military production. He also questions Einstein's alleged destruction of his theories, suggesting that military secrets are well-guarded and that modern satellite surveillance would make such an experiment impossible to hide.

Regarding psychotronic generators, Akimov acknowledges the public's concern but states he has not personally seen any such devices. He believes that reported effects are often sensory or collective psychological phenomena, possibly influenced by mass meditation techniques. He distinguishes between influencing behavior (psychotronic) and causing physical discomfort (e.g., from strong magnetic or electric fields). He also notes that some individuals claiming to be affected by psychotronics may be seeking attention or medical help.

Vasily Lensky and the "Zombie" Program

The article mentions Vasily Lensky, who developed multipolar generators and psychotronic devices. Lensky reportedly refused to conduct his research in secret, leading to the death of his students and his own laboratory's destruction. Akimov suggests that most people claiming to be victims of psychotronic воздействие (influence) are in need of medical attention, with a smaller percentage being manipulators.

He dismisses claims in "Komsomolskaya Pravda" about the MNTZ VENT receiving 500 million rubles for psychotronic generators, calling it a "nonsense" and a "hoax." Akimov clarifies that his institute focuses on ecologically clean and resource-saving technologies and that the claims about the "Zombie" program and the "Octava" plant are unfounded.

Author and Source Information

The article is attributed to Anatoly Evgenyevich Akimov, Academician of RAEN, Doctor of Physical and Mathematical Sciences, and General Director of the Inter-branch Scientific and Technical Center for Venture Nontraditional Technologies, as well as Director of the International Institute of Theoretical and Applied Physics. The interview was conducted by V. Landa and N. Glazkova. The source is cited as "Svet" magazine, 1999, №3.

Recurring Themes and Editorial Stance

The recurring themes in this issue revolve around alternative physics, particularly torsion fields and their potential applications in energy generation and advanced technologies. The editorial stance appears to be one of exploring and presenting these unconventional scientific ideas, while also addressing skepticism and potential controversies. The magazine provides a platform for figures like Anatoly Akimov to present their theories and research, encouraging a broader discussion on the frontiers of science, including topics like psychotronics and the possibility of technologies derived from UFO phenomena. There is an underlying theme of challenging established scientific paradigms and exploring possibilities that lie beyond mainstream understanding, with a particular emphasis on environmentally friendly and resource-saving technologies.