(AI Generated Image) (October 18, 2024)
Speaking with the original person that I captured the "Jerry Files" @RebeccaRamaley she wrote me and I understood she has made a connection to "creating gems as metamaterials". I said I didn't know about that and that I'd help her look into it.
Interestingly, when I logged into my Facebook UAP group where I'd shared the Missing Jerry page with the schematics, it was met with a response from a local UAP member saying "A lot of these diagrams show principals I learned studying mineralogy. The first diagram is the same as how light propogated through calcite. Lightwave splits at the right angles as it propogates through the crystal." (M. M., 2024)
Now, I feel obligated to side-quest and see if there is a connection.
I started looking where @RebeccaRamaley said to start.
I plugged in some things into Chat GPT: "The invention of the maser (microwave amplification of stimulated emission of radiation) in 1954 by Charles Townes and Arthur Shawlow led to new investigations into light amplification by stimulated emissions of radiation, or laser, a term coined by American physicist Gordon Gould in 1957. Can this work be connected to the work of Larry Reed?"
This is what I got back:
1. Key Concepts from the Diagrams
The diagrams depict three types of materials and their associated Doppler effects:
Positive Index Material Resonator (Doppler Effect)
Zero Index Metamaterial Resonator (No Doppler Effect)
Negative Index Metamaterial Resonator (Inverse Doppler Effect)
These concepts show how waves behave in different kinds of materials, specifically resonators that have positive, zero, or negative refractive indices.
Effective Mass and Resonator Behavior:
The equations in the diagrams describe effective mass and how resonators respond to waves (such as electromagnetic or sound waves). The effective mass of the system changes depending on the material's refractive index.
Out-of-phase oscillation and blue-shift/red-shift effects are shown, demonstrating the resonator’s response to frequency changes as waves pass through them.
Relation to Maser/Laser Technology:
The maser (Microwave Amplification by Stimulated Emission of Radiation) operates by amplifying microwaves using atomic transitions, while the laser (Light Amplification by Stimulated Emission of Radiation) extends this principle to visible light.
Both masers and lasers rely on resonators (cavities that trap light or microwaves) to create standing waves and amplify specific frequencies of radiation.
The resonators shown in the diagram, especially those that involve standing waves and frequency shifts, could theoretically be applied in designing advanced lasers or masers. The manipulation of waves—through shifting their frequencies (Doppler effect) or altering their speed using different refractive indices—is fundamental to amplifying and controlling electromagnetic radiation, just like in maser/laser systems.
2. Larry Reed’s Work
Without specific information on the exact contributions of Larry Reed, it's difficult to definitively connect his work to these diagrams. However, if Reed’s work involved advanced resonator technologies, wave manipulation, or metamaterials, it is possible that his research could relate to these principles.
Possible Connections:
If Reed worked in microwave technologies or optical systems, such as metamaterials for controlling waves (akin to how masers/lasers work), his contributions could be tied to the ideas in the diagrams—especially in terms of resonator design and wave manipulation.
Reed may have focused on advancing materials that change how waves interact with them, like negative index metamaterials, which have been used in creating new types of lenses, cloaking devices, or energy systems. These concepts could, in turn, enhance microwave or optical amplification technologies.
3. Applications in Today's World
The combination of metamaterials and resonator physics shown in the diagrams has broad implications for modern technologies:
Cloaking and Stealth Technologies: Metamaterials that bend light or microwaves in unusual ways are central to creating cloaking devices, as negative-index materials can redirect waves around objects.
Advanced Communications: Resonators that manipulate waves are crucial in microwave communications and radar systems. These could enhance the next generation of wireless communication (5G/6G).
Quantum Computing and Sensors: The fine control of wave behavior, especially through zero-index and negative-index metamaterials, can be used in quantum devices where controlling light and matter interactions is key.
Summary:
The diagrams you've provided illustrate advanced wave manipulation using resonators and materials with unusual refractive indices. These concepts directly relate to maser and laser technology, where controlling the behavior of light or microwaves is essential for amplification and precision. If Larry Reed’s work involved wave resonators, metamaterials, or microwave systems, it could indeed intersect with these principles.
This image is from their website, where there are drop down menus for different materials.
Notice, everything from Silicone MEMS, to Metallurgy, to Nanotech, all the way to polymer and coating design. Each with a description.
So, I'm gathering this company does a lot more than make Lasers and Masers.
I believe @RebeccaRamalay is on another bread trail to something we aren't supposed to know.
So here, "At 10,000 square feet, our ISO Level 4 cleanroom supports multiple product lines and is a DoD/NSA Category 1A Trusted Foundry. MTL has an ISO 9001 quality certification for the manufacture and test of semiconductor wafers as well as an AS9100 quality certification for certain products used in aerospace applications. Our manufacturing capabilities and full product support include:" At least from my perspective, a Level 4 (Clearance) Cleanroom would be the IDEAL place to produce metamaterials that require zero-gravity and extreme cold temperatures... No?
I'm in this with you all and I look forward to learning more.
If Disclosure happened in front of your eyes and went away in less than 10 minutes, what would you think? How many times have you been tricked that if the truth were right in front of your face you'd still deny it?
Now let's peek at JPL (Jet Propulsion Laboratory)
Facts about JPL
Designed, built, and operated the United States’ first satellite, Explorer 1, launched in 1958. Explorer 1 produced the first-ever scientific result from space: the discovery of the Van Allen Radiation Belts.
Explored all the solar system’s planets, from Mercury to Neptune.
Developed and operated the first rotorcraft ever sent to another planet.
Designed, built and operated all five of the successful rovers sent so far to the surface of Mars.
In Earth science, pioneered radar scatterometry for ocean surface wind measurements, radar altimetry for sea surface height, synthetic aperture radar for natural hazard and solid earth applications, gravity measurements to characterize Earth’s cryosphere and water cycle, and a number of spectrometer advances for atmospheric sounding and land surface measurements.
Led development of space-based infrared astronomy with such missions as the Infrared Astronomical Satellite, the Spitzer Space Telescope, and the Mid-Infrared Instrument on the James Webb Space Telescope.
Developing technology projects such as advanced atmosphere entry systems, advanced detectors for a wide variety of airborne and spaceborne instruments, laser communications, cubesat-based investigations, and robotic technologies for both autonomous operation and use by human explorers.
The Laboratory’s core capability is to integrate science, engineering and technology that provide end-to end implementation of space missions, through either use of its in-house experienced workforce or in collaborations with industry and academia.
JPL also applies its capabilities to national security in areas synergistic with its work for NASA, and develops technologies for uses on Earth in fields from public safety to medicine, capitalizing on NASA’s investment in space technology.
Operates the NASA Deep Space Network, enabling navigation and data return throughout the solar system.
40 currently active missions.
Annual budget for fiscal year 2021 $2.4 billion.
Approximately 6300 employees and on-site subcontractors at a 168-acre facility in the foothills of the San Gabriel Mountains near Pasadena, California.
(Tom Hoffman, InSight Project Manager, NASA JPL, left, and Sue Smrekar, InSight deputy principal investigator, NASA JPL, react after receiving confirmation that the Mars InSight lander successfully touched down on the surface of Mars, Monday, Nov. 26, 2018 inside the Mission Support Area at NASA's Jet Propulsion Laboratory in Pasadena, California. InSight, short for Interior Exploration using Seismic Investigations, Geodesy and Heat Transport, is a Mars lander designed to study the "inner space" of Mars: its crust, mantle, and core. Photo Credit: (NASA/Bill Ingalls)
Credit: NASA/JPL-Caltech)
This will determine your beliefs in the phenomena, otherwise the government gets all the control. You have make up your own mind.
Stay curious. Question Everything.
Stellabulator
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