As part of the “Galileo” project, chaired by Harvard University professor Avi Loeb, many microscopic balls bearing meteorite origins were found. These fragments may well be part of the first meteorite recorded from outside our solar system and have the potential to reveal extraordinary alien technology.

an interstellar object

Professor Avi Loeb was the first to describe the tagged meteorite. CNEOS 20140108 As an interstellar object in the NASA catalogue. The meteor caused three visible flashes recorded by the US military near Papua New Guinea in January 2014.

Analysis of the object’s luminosity curve showed that it was a celestial body measuring between 80 and 100 centimeters and weighing about 460 kilograms. However, the most surprising discovery was his incredible speed – 60 kilometers per second, showing its extraterrestrial origin. Later, the US military informed the authorities that the object really belongs to the category of interstellar objects.

To search for alien technologies

Avi Loeb stated in one of his early articles that the meteorite exploded when it encountered air resistance much stronger than any other object registered in the NASA catalog. This finding suggested that the meteorite material had a higher durability than any other known space rock.

The Pentagon and American scientists have long fueled speculation about the existence of extraterrestrial technology on Earth, and the Galileo project, co-founded by Avi Loeb, was created for a similar purpose. Searching for the remains of the first recognized interstellar meteorite, designated IM1, became one of the main goals of the project team.

The possibility of IM1 being the interstellar probe of an extraterrestrial civilization intrigued researchers. After all, it’s not surprising to consider the same scenario for IM1, just as our Voyager spacecraft might eventually collide with an exoplanet and burn up in its atmosphere.

Search Results

Searching for IM1 meteorite fragments using a magnetic trawl yielded promising results. By sieving magnetic particles of volcanic origin, the researchers were able to identify the magnetic samples. size less than one millimeterdistinguishable from “background” particles collected from the control region.

Detailed analysis showed that these particles were composed of 84% iron, 8% silicon, 4% magnesium and 2% titanium, as well as trace elements. Also, isotopes of uranium and lead were detected in the samples, making it possible to estimate their age based on the half-life of uranium. Data from these samples indicate age. 13.8 billion yearscontrol samples age 4.6 billion years (age of the solar system). This once again confirmed the interstellar origin of the IM1 meteorite.

These submillimeter spheres, which look like thin metal balls under a microscope, are concentrated along IM1’s predicted path, about 85 kilometers off the coast of Manus Island in Papua New Guinea, Loeb says. According to the scientist, their discovery represents a new milestone in astronomy when the study of what lies beyond the boundaries of the solar system goes beyond the scope of telescopes and moves into the field of microscopes.