Art’s Parts 2: UFO Crash Recovery SEM & Materials Analysis

Jarod Yates provides updates on his research into a verified sample of the “Art’s Parts” purported crash wreckage material, past scientific claims of levitation in the 5 Terahertz regime, the Bismuth/Magnesium layering, possible quasicrystal composition, and upcoming tests. Mark Sokol and Jarod Yates recently performed visual analysis using a metallurgical microscope, SEM analysis at a nearby lab, and are researching Raman spectroscopy options as well.

In this presentation, Jarod Yates details the ongoing analysis of the “Art’s Parts” metallic sample under investigation by Falcon Space. Scanning electron microscopy (SEM) and energy dispersive spectroscopy (EDS) reveal zinc-encased lead microspheres, some ruptured—an unusual phenomenon. The sample, approximately 7mg, shows intriguing symmetrical patterns and elemental composition (carbon, oxygen, magnesium, zinc, bismuth, lead), raising questions about its origin. The speaker speculates on a non-prosaic origin, possibly not from 20th-century military testing, citing similarities to structures in Gary Nolan’s research (Soul Foundation video).

Further analysis, including Raman spectroscopy and advanced microscopy techniques, is planned to determine the material’s composition and origin, with hypotheses ranging from advanced terrestrial technology to extraterrestrial or even interdimensional sources. High-resolution images are available for public analysis via a provided Google Drive link. The speaker highlights the potential significance of the sample’s unique characteristics, comparing its discovery to finding a 747 in King Tut’s tomb.

A Closer Look: Scanning Electron Microscopy (SEM) and Energy Dispersive Spectroscopy (EDS)

The analysis centers around SEM and EDS imaging, techniques that reveal the sample’s structure and elemental composition at a microscopic level. The sample, roughly the size of a small penny (4mm x 2.5mm x 0.4mm) and weighing 7mg (including epoxy), revealed a stunning array of features:

• Zinc-Encased Lead Microspheres: The most striking discovery is the presence of numerous zinc-encased lead microspheres, many of which appear ruptured. This is an unprecedented observation, leading to speculation about their function. A hypothesis suggests they may act like overcharged capacitors. (00:02:00)
• Intriguing Symmetries: The arrangement of these microspheres isn’t random; it exhibits fascinating symmetries and patterns, including recurring 90-degree angles within circular structures. Some structures even display a peculiar three-legged configuration. (00:03:00)
• Elemental Composition: EDS analysis reveals a complex mix of elements, including carbon (likely a pollutant), oxygen (oxidation), magnesium, zinc, bismuth, and lead. The presence of aluminum and niobium is considered potential noise. (00:04:00)
• Bismuth Nanospheres and Delamination: A bismuth layer is observed, delaminating from a magnesium layer, with a transition zone containing zinc and magnesium. The bismuth side showcases intricate geometric structures and divots in the shearing layer. (00:05:00)
• The Mysterious Fiber: A 90-degree fiber was also found within the sample. Microscopic analysis suggests it may be a whisker, not a manufactured fiber. (00:08:00)

Beyond the Microscopic: Connecting the Dots

The presenter highlighted several intriguing aspects:

• Water Reactivity: The sample reacts to water, exhibiting cavitation and a redox reaction, suggesting a potential interaction between zinc and magnesium with water to produce hydrogen. (00:06:00)
• Possible High-Energy Environment: The presence of sodium, detected near the threshold, hints at a possible high-energy environment, such as a nuclear reactor or exposure to gamma radiation, potentially leading to element transmutation. (00:10:00)
• Quasicrystal Correlations: The arrangement of elements and the observed geometric structures show a significant correlation with quasicrystal structures, though further testing (Raman spectroscopy) is needed for confirmation. (00:11:00)
• Golden Ratio Proportions: The distances between certain dots in the sample appear to approximate the golden ratio, further supporting the quasicrystal hypothesis. (00:11:00)

The Roswell Connection and Beyond:

The presenter discussed purported documents related to the Roswell incident, suggesting the sample might be connected to the infamous 1947 crash. These documents mention a toroid-shaped device, possibly a neutronic/atomic engine, and list elements like uranium, magnesium, plutonium, and thorium, consistent with a fusion/fission reactor. (00:09:00) The documents also describe fine grid-like lines and intersecting dots in circular patterns, strikingly similar to the sample’s microscopic features. (00:11:00)

Hypotheses and Future Testing:

The presenter emphasized that the following are speculative hypotheses based on previous research:

• Terrestrial, but Out-of-Place: The sample could be a product of time-traveling humans, a breakaway civilization, or an ancient advanced civilization. (00:12:00)
• Extraterrestrial Origins: The possibility of interdimensional origins, a multiverse origin, or an immaterial realm transitioning to the material realm were also discussed. (00:12:00)

Future testing includes metallurgical microscopy, Raman spectroscopy, scanning tunneling microscopy, and atomic force microscopy. Gamma ray testing is underway to detect radiation, and further tests are planned for November, including a live stream of the sample under a microscope. (00:12:00)

Conclusion:

The analysis of this enigmatic sample presents a compelling case for further investigation. The unique combination of materials, their arrangement, and the potential connections to the Roswell incident demand a deeper understanding. The ruptured zinc-lead microspheres, the intricate geometric patterns, and the potential quasicrystal structures challenge our current scientific understanding and open up a world of possibilities. Stay tuned for updates as further testing unfolds! Links to additional resources, including high-resolution images, are available in the presentation comments section. (00:13:00)