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air-force-mrt-instability-research

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Executive Summary

This research explains how tiny dust particles suspended in plasma can become 'entangled'—a quantum state where their actions are linked—even though they are large enough to see. The study shows that by using specific plasma waves, scientists can create and measure this connection between macroscopic particles, effectively bringing quantum physics into the visible world.
Analysis Confidence: High
ST_CODE: A3C331

System Metadata

Source ID

DOC-ISHIHARA

Process Date

2/3/2026

Integrity Hash

SHA256-12lhqh5x5zu9...

Indexer Status

COMPLETE

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INVESTIGATIVE ANALYSIS

Layman's Executive Summary

This research explains how tiny dust particles suspended in plasma can become 'entangled'—a quantum state where their actions are linked—even though they are large enough to see. The study shows that by using specific plasma waves, scientists can create and measure this connection between macroscopic particles, effectively bringing quantum physics into the visible world.

Document Origin

The document was authored by Osamu Ishihara, affiliated with the Faculty of Engineering at Yokohama National University and Chubu University in Japan. It was published in the peer-reviewed journal 'Physics of Plasmas' by the American Institute of Physics (AIP).

Research Purpose

The research aims to apply quantum mechanical frameworks to macroscopic 'complex plasmas' to determine if dust particles can exhibit entanglement. It seeks to solve how these large, highly charged particles interact through virtual waves (quasi-particles) and how their collective behavior can be controlled via external plasma waves.

Relevancy Analysis

" This document is highly relevant to advanced aerospace and energy research as it bridges the gap between quantum entanglement and macroscopic plasma dynamics, a field essential for Field Reversed Configuration (FRC) and fusion stability. The presence of the 'SecretMilitaryTechnology.com' watermark suggests that this theoretical breakthrough in plasma coupling is being monitored for potential applications in non-conventional propulsion or directed energy programs. "

Extracted Verifiable Claims

  • The article was published in Physics of Plasmas, Volume 31, Issue 3, Article 032118 on March 27, 2024.
  • The research identifies the trigger frequency for dust entanglement as one-half of the dust plasma frequency.
  • The DOI for the research is 10.1063/5.0192854.
  • Osamu Ishihara is the sole author, with a present address in Nerima-ku, Tokyo, Japan.
  • The study utilizes the method of second quantization to formulate the Hamiltonian for the two-particle system.

Technical Contribution

The paper identifies the specific trigger for macroscopic entanglement in complex plasmas as being an injected wave frequency exactly equal to one-half of the dust plasma frequency.

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Transcript

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INTRODUCTION

 View Online  Export Citation RESEARCH ARTICLE| MARCH 27 2024 Entanglement in a complex plasma Osamu Ishihara Phys. Plasmas 31, 032118 (2024) https://doi.org/10.1063/5.0192854 Articles You May Be Interested In Quantum entanglement for helium atom in the Debye plasmas Phys. Plasmas (March 2015) Dual monogamy inequality for entanglement J. Math. Phys. (January 2007) Entanglement, Bell inequality and all that J. Math. Phys. (July 2012) 11 September 2025 15:23:46 Entanglement in a complex plasma Cite as: Phys. Plasmas31, 032118 (2024);doi: 10.1063/5.0192854 Submitted: 20 December 2023 . Accepted: 1 March 2024 . Published Online: 27 March 2024 Osamu Ishihara a) AFFILIATIONS Faculty of Engineering, Yokohama National University, Yokohama, 240-8501, Japan and Chubu University, Kasugai, Aichi-Pref., 487-8501, Japan a) Present address:Nerima-ku, Tokyo, Japan. Author to whom correspondence should be addressed:[email protected]