Art’s Parts 3: UFO Crash Recovery Terahertz & Quasicrystals
Jarod Yates presents detailed analysis of Art’s Parts & other UAP samples. He has coordinated SEM, XRD, NAA, and several other analytical methods for 2 separate samples from the Art’s Parts collection, along with San Augustin, Dalnegorsk and Roswell Skip Site samples.
Jarod, in collaboration with various experts and utilizing advanced microscopy techniques (SEM, EDS, TEM), details the materials’ unique composition—including zinc, lead, magnesium, and potentially bismuth—and nanometer-scale structures. Analysis reveals a possible correlation between the materials’ properties and terahertz frequencies, particularly within the “magic window” (3.2-5.6 THz).
Jarod connects these findings to previous research on programmable quantum matter, quantum dots, and the unusual properties of bismuth nanowires. Comparisons are drawn to other anomalous materials, such as those from the 1986 Dalnegorsk event and Ubatuba, highlighting similarities and differences.
This presentation also touches upon a classified 2024 Oak Ridge National Lab report, which the speaker deems inadequate, and the challenges of replicating the observed technology. The speaker concludes by emphasizing the need for further peer review and research, particularly concerning the potential of terahertz radiation in UFO propulsion systems.
A Journey Through Decades of UAP History and Scientific Investigation
The journey began with the acquisition of fragments from the infamous 1947 Roswell incident, specifically “Arts parts,” materials whose history traces back through various owners, including Art Bell and Linda Moulton Howe. These materials, along with samples recovered in 2011 and a Falcon space sample, formed the basis of an extensive investigation. [Speaker 1] collaborated with experts possessing access to advanced laboratory equipment, facing threats and challenges along the way (details of which can be found on Reddit).
Advanced Material Analysis: Microscopy and Spectroscopy Reveal Astonishing Details
The analysis involved sophisticated techniques including scanning electron microscopy (SEM), electron dispersive spectroscopy (EDS), and transmission electron microscopy (TEM). The SEM revealed inconsistencies confirming initial observations, highlighting crucial details within the samples. One sample, potentially containing a significant indicator of advanced technology, was discarded.
The microscopic analysis revealed nanometer-sized structures, suggesting a level of engineering and technology far beyond our current understanding. The team observed:
- Microsphere Ring Arrangement: Ruptured microspheres arranged in a ring pattern, particularly evident in the Falcon space sample. Larger spheres were ruptured, while smaller ones remained intact, suggesting a process or function.
- Elemental Composition: EDS analysis revealed a composition of zinc, lead, and oxygen. Smaller, unruptured spheres were primarily zinc (sometimes oxidized) with lead present, and exhibited a hollow interior.
- Nanowire Structures: TEM images revealed 10-nanometer structures, potentially forming waveguides through zinc grain spacing.
- Whiskers: Micron-sized whiskers were observed, possibly indicating prolonged exposure to an electric gradient and possessing terahertz properties. The composition of these whiskers remains uncertain, with bismuth, zinc, or a combination being possibilities.
The Significance of Terahertz Frequencies
The research highlighted the importance of the terahertz (THz) frequency range (1-10 THz), a difficult-to-access range crucial to understanding the materials’ function. The “magic window” of 3.2-5.6 THz was identified as particularly significant, potentially correlating with observed UFO temperatures. The study also explored the potential connection between terahertz radiation and biological effects, referencing research on cow blood albumin and the impact on microtubules and DNA.
Connecting the Dots: Quantum Dots, Nanowires, and Programmable Quantum Matter
The analysis revealed striking similarities between the samples and research on programmable quantum matter and quantum dots. The presence of zinc-coated lead quantum dots, capable of converting ambient heat into coherent terahertz radiation, is a compelling possibility. The researchers also noted similarities between the samples and the materials described in Eric Davis’s 2009 Defense Intelligence document, which mentioned nanowires and quantum dots in relation to advanced materials.
The Down the Gorsk Event and Quincy St. Clair’s Patent: Further Clues
The research also explored connections to the 1986 Down the Gorsk event in Russia, which yielded materials with striking similarities to the Arts parts, including gold nanowires and ruptured zinc-lead microspheres. The similarities, along with differences suggesting potential transmutation, raise intriguing questions about the origin and nature of these materials. The researchers also drew parallels to Quincy St. Clair’s 2004 patent on braided gold coaxial cables, noting the potential connection to dimensional manipulation.
A Terahertz Laser and Isotopic Analysis: Further Investigations
The researchers acquired a terahertz laser, currently undergoing servicing, and conducted isotopic analysis, revealing unusual neutron absorption at high energy. The sample exhibited temporary radioactivity, adding another layer of complexity to the analysis.
Conclusion: A Glimpse into the Future of Material Science
This research provides compelling evidence of advanced material science far beyond our current capabilities. The findings suggest the possibility of programmable quantum materials, terahertz technologies, and potentially even dimensional manipulation. While much remains to be investigated, this research opens up exciting new avenues for understanding UAP and pushing the boundaries of material science. Further updates will be provided as the analysis of the remaining three samples progresses. The researchers express gratitude to the scientists involved and anticipate further developments.