UFO and UAP Anti Gravity Vehicles Use These Metals

The Roswell UFO crash of 1947 remains one of the most famous and debated UFO crash events in history. It began when a rancher named Mac Brazel discovered unusual debris on his property near Roswell, New Mexico, leading to initial military reports claiming they had recovered a “flying disc.”

However, this narrative was quickly retracted, and the military clarified that the debris was from a weather balloon involved in Project Mogul, aimed at monitoring Soviet nuclear tests. Despite this explanation, conspiracy theories about alien spacecraft and government cover-ups have proliferated, with many claiming that alien bodies were recovered and hidden away. Over the years, the incident has become emblematic of UFO lore, inspiring countless books, documentaries, and turning Roswell into a hub for UFO enthusiasts and tourists.

At the Roswell crash sight were many items found, in this blog we will discuss the types of metals found from the Roswell UFO crash site. Discovered by many witnesses.

These are the 7 main metals used for UFOs and anti-gravity:

1. Liquid Mercury: Research suggest that liquid mercury is used in anti-gravity technology, although this is not backed by peer-reviewed scientific articles but rather by anecdotal or speculative claims from social media.
2. Iron: Iron is one of the most abundant metals on Earth, known for its strength, durability, and magnetic properties. Used extensively in construction, manufacturing, and transportation, iron forms the backbone of many industries. In terms of electrical conductivity, iron has a moderate level. Its electrical conductivity is approximately 1.04 x 10^7 Siemens per meter (S/m), which translates to roughly 18% of the International Annealed Copper Standard (IACS). This lower conductivity compared to other metals like copper makes iron less ideal for applications requiring high electrical performance, such as in electrical wiring. However, its affordability and strength mean it is used in applications where conductivity isn’t the primary concern, like in structural components.
3. Copper: Copper is widely recognized for its excellent electrical conductivity, making it the standard against which other metals are often measured. Its electrical conductivity is approximately 5.8001 x 10^7 S/m, which is defined as 100% IACS. This high conductivity, along with copper’s malleability and ductility, makes it the prime choice for electrical wiring, power transmission lines, and electronic components. Beyond its electrical properties, copper is also valued for its thermal conductivity, corrosion resistance, and antibacterial qualities. In industries, copper’s role extends from telecommunications to high-tech manufacturing, where its ability to conduct electricity efficiently without significant energy loss is crucial.
4. Zirconium: Zirconium is a lustrous, grey-white, strong transition metal, known for its corrosion resistance, particularly in acidic environments. It’s primarily used in nuclear reactors due to its low neutron absorption cross-section and in chemical processing where high resistance to corrosion is required. The electrical conductivity of zirconium is relatively low compared to metals like copper or iron, with a conductivity of about 2.36 x 10^6 S/m, which is roughly 4% IACS. This makes zirconium more suitable for applications where electrical conductivity is not a priority, but its other properties like resistance to extreme conditions are beneficial. Zirconium is also alloyed with other metals to improve their mechanical properties without significantly affecting their electrical conductivity.
5. Molybdenum: Molybdenum is a silvery-white, hard, transition metal, known for its high melting point (2,623 °C or 4,753 °F) and resistance to corrosion. It is primarily used in alloys to enhance strength, hardness, and resistance to wear and corrosion, especially in steel where it improves toughness and resistance to high temperatures. Molybdenum’s electrical conductivity, while not as high as that of copper, is still significant; it has an electrical conductivity of about 1.87 x 10^7 S/m, which is roughly 32% of the IACS. This conductivity level makes molybdenum suitable for applications where both electrical properties and mechanical strength are important, such as in electrical contacts in high-temperature environments or in components of electronic devices that require resistance to thermal shock. Molybdenum’s conductivity is leveraged in areas where materials need to perform under harsh conditions. For instance, molybdenum is used in the manufacture of electrodes for electrically heated glass furnaces, where the metal’s ability to conduct electricity, combined with its resistance to oxidation and high temperatures, is crucial. It also finds use in the semiconductor industry, where molybdenum’s properties help in creating thin films or layers with good electrical conductivity for microelectronics. However, its application in bulk electrical conductivity scenarios is less common due to its higher cost and the presence of more conductive materials like copper or aluminum for such purposes. Nevertheless, its unique combination of electrical, thermal, and mechanical properties ensures molybdenum remains a material of choice for specialized high-performance applications.
6. Element 115: known scientifically as Moscovium, has been a subject of intrigue and speculation, particularly in the realm of UFO lore, thanks to Bob Lazar’s claims in the late 1980s. Lazar, who alleged he worked on reverse-engineering alien technology at Area 51, described element 115 as a key component in creating an anti-gravity propulsion system for extraterrestrial spacecraft. According to Lazar, this element was stable and could produce its own anti-gravitational field when exposed to radiation. Some say Moscovium was officially synthesized by a team of Russian and American scientists in 2003, and it is far from stable. It has a very short half-life of about 0.65 seconds, meaning it decays rapidly into other elements. This starkly contrasts with Lazar’s claims of a stable isotope capable of long-term use in propulsion systems. Recent advancements in quantum mechanics and particle physics have brought us closer to understanding superheavy elements like Moscovium. Researchers have been experimenting with new methods to synthesize these elements, exploring the potential for isotopes with longer half-lives or even theoretical stable forms. While there’s no evidence supporting Lazar’s claims about element 115’s properties, the scientific journey towards understanding these superheavy elements continues, driven by curiosity and the quest for knowledge. The fascination with element 115 extends beyond science into popular culture, where it’s a staple in discussions about UFOs and extraterrestrial technology. Whether or not element 115 will ever play a role in advanced technology as Lazar envisioned remains speculative, but the pursuit of scientific discovery keeps the door open to possibilities once thought unimaginable.
7. Superconductors: All of these metals above are considered superconductors. While not a metal itself, the use of superconducting materials like niobium-titanium or yttrium barium copper oxide, which are often metals or metal oxides, has been discussed in the context of anti-gravity research. Superconductors can create magnetic fields that might interact with gravity in unique ways.