"Confinement of Light: Standing Wave Transformations in a Phase-Locked Resonator"
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(February 05, 2025)
Larry Reed released a new paper (February 2025) on electromagnetic resonant wave interactions in a phased-locked resonator at rest and in motion are compared. The origin of mass and inertia as a standing wave interaction in a phased-locked cavity as demonstrated in work by Jennison is reviewed and phase relationships illustrated. For matter (composed of resonant EM standing waves) in motion, the Lorentz contraction is interpreted as a physical wavelength compression due to variation in EM field energy density as measured by vacuum refractive index KPV. Dipole radiation emitted from a phase-locked resonator in motion is described. A graphical representation of Ivanov-LaFreniere standing wave transformations is shown. Experimental possibilities for potential phase conjugate wave phase-locked resonator development are discussed. Keywords: electromagnetic (EM), standing wave, photon, phase-locked resonator, confined light, Lorentz, mass, frequency, oscillator , inertia, phase conjugate waves.
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Here is an AI analysis of the paper.
This paper discusses experimental and theoretical research on phase-locking effects in resonators and their interaction with electromagnetic (EM) waves, with implications for novel propulsion concepts and exotic wave phenomena.
Key Concepts:
Phase-Locking of Resonators:
The research builds on experiments by Jennison in the 1980s, where free-floating resonators were phase-locked using light and microwaves. A key finding was that a source emitter and a reflector moved together as if mechanically connected, with spacing accuracy better than 0.001 wavelengths.
Wave Manipulation and Inverse Effects:
The paper discusses the ability to halt and reverse EM waves without reflection or refraction.
It references inverse effects such as the inverse Doppler effect, inverse Sagnac effect, and inverse piezoelectric effect, implying unconventional energy or motion behaviors.
Metamaterials and Nonlinear Effects:
The research connects to metamaterials, nanostructures, and MEMS technologies, which enable unusual wave properties like negative refraction, phase conjugation, and slow light.
Asymmetric resonators with a graded index of refraction could introduce nonlinear force effects.
Potential for Force Amplification and Propulsion:
By modulating phase-conjugate waves and pumping a nonlinear medium at double the incident frequency, a force could be amplified, possibly leading to net motion of a resonator.
The paper suggests that a self-induced motion mechanism might be possible, where EM pump waves act on a phase-conjugate mirror (PCM), generating an unbalanced radiation pressure.
Energy Flow and Relativistic Considerations:
The phase relationship between signal and pump waves determines whether energy is amplified or deamplified. The energy equation provided suggests a relativistic-like approach to motion, where external force application could induce wave system velocities.
Possible Implications:
This research could have applications in advanced propulsion, particularly in non-traditional methods of generating thrust without expelling mass.
It explores the fundamental relationship between waves and inertia, possibly hinting at ways to manipulate motion using purely electromagnetic interactions.
Final Thoughts:
The paper discusses a combination of wave physics, resonator dynamics, and metamaterial properties to explore new mechanisms for motion and force manipulation. While the experimental verification of some concepts remains unclear, the ideas presented suggest potential breakthroughs in wave-driven propulsion, force manipulation, and energy transfer mechanisms.
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