Remote Field Effect

Remote Field Effect

Non-Local Interaction and Torsion-Based Models

What Is the Remote Field Effect?

The Remote Field Effect refers to interactions that appear to occur without direct physical contact, mediated through structured fields rather than conventional mechanical or electromagnetic transmission.

In theoretical models, such effects are described as:

  • Field-based interactions,
  • Information-mediated influence,
  • Non-local or extended coupling between systems.

These models explore whether physical systems can exchange structured information across space through field configurations rather than direct energy transfer.

Theoretical Foundations

Several theoretical ideas contribute to the Remote Field Effect concept:

  • Time as an active factor (Kozyrev):
    Irreversible processes may generate directional field effects associated with time.
  • Negentropy and information:
    Order and structure can propagate through informational patterns rather than material exchange.
  • Phase coherence:
    Coherent wave structures preserve information across distance.
  • Torsional space-time models:
    Rotational and spin-related geometries may support non-classical field propagation.

Together, these ideas suggest that structured fields could transmit informational influence beyond direct physical contact.

Akimov’s Torsion Field Research

Anatoly E. Akimov (1939–2015) proposed that certain physical systems could generate and detect torsion fields, described as spin-related field components distinct from electromagnetic radiation.

  • Torsion fields are associated with particle spin and rotational asymmetry,
  • They are proposed to propagate without conventional energy loss,
  • They are proposed to interact with matter through structural rather than energetic mechanisms.

He also described experimental device concepts sometimes called torsion generators, intended to produce torsion-like effects using rotational or asymmetric configurations.

The Small Torsion Generator Model

The Remote Field Effect is implemented conceptually using a compact torsion generator inspired by torsion-generator design principles.

Such a generator typically includes:

  • Rotational or asymmetric field structures,
  • Phase-structured excitation,
  • Geometric configurations designed to emphasize spin and asymmetry.

The generator emphasizes:

  • Structural field configuration,
  • Phase relationships,
  • Informational patterning.

It functions as a field interface between:

  • The informational signal (matrix or pattern),
  • And the surrounding space-time field.

Non-Local and Informational Interaction

In torsion-based interpretations:

  • The interaction does not require direct energy transmission,
  • Information may be transferred through geometric or spin-based coupling,
  • Distance plays a reduced role compared to classical field models.

This aligns conceptually with:

  • Non-equilibrium thermodynamics,
  • Information-based physics,
  • Extended field theories.

These ideas remain outside mainstream physics and are considered exploratory.

Scientific and Critical Context

“Torsion field” claims in the Akimov/Shipov sense are widely treated as controversial. Separately, torsion is a well-defined mainstream concept in differential geometry (torsion tensor) and appears in some gravity extensions (e.g., Einstein–Cartan).

Relevance to Informational Field Technologies

From a technological perspective, the Remote Field Effect model focuses on:

  • Structured field generation,
  • Phase coherence,
  • Informational pattern delivery.

The generator is treated as a structural modulator and carrier for informational waveforms, enabling exploration of field-mediated interaction without relying on chemical or mechanical intervention.

Summary

The Remote Field Effect describes a theoretical form of interaction mediated by structured fields rather than direct contact.

It is conceptually based on:

  • Time-related irreversibility,
  • Information and negentropy,
  • Phase coherence,
  • Torsional space-time models,
  • Akimov/Shipov torsion-generator concepts.

Together, these ideas propose that structured field configurations may support non-local informational coupling between systems.

References (for the bottom of the page)

  • Spin and Torsion in Gravitation – Hehl et al. (Reviews of Modern Physics)
    https://journals.aps.org/rmp/abstract/10.1103/RevModPhys.48.393
  • Torsion tensor (Differential Geometry) – Wikipedia
    https://en.wikipedia.org/wiki/Torsion_tensor
  • Einstein–Cartan theory – Wikipedia
    https://en.wikipedia.org/wiki/Einstein%E2%80%93Cartan_theory
  • Non-Equilibrium Thermodynamics and Time’s Arrow – Stanford Encyclopedia of Philosophy
    https://plato.stanford.edu/entries/time-thermo/
  • Information and Entropy – Stanford Encyclopedia of Philosophy
    https://plato.stanford.edu/entries/information-entropy/