Astronomers in Japan have reported evidence that a small, icy world beyond Pluto may possess a thin atmosphere—an unexpected finding that could reshape understanding of the outer Solar System.
The object, known as (612533) 2002 XV93, lies in the distant Kuiper Belt, roughly six billion kilometres from Earth. Measuring about 500 kilometres across, it would become only the second known trans-Neptunian object with an atmosphere, after Pluto, if the discovery is confirmed.
The research, led by Ko Arimatsu of the National Astronomical Observatory of Japan, was based on observations made in January 2024. Scientists detected unusual behavior in starlight as the object passed in front of a distant star—light that dimmed and reappeared gradually, suggesting the presence of a thin gaseous layer.
According to findings published in Nature Astronomy, the atmosphere could be between five and ten million times thinner than Earth’s.
The discovery challenges long-held assumptions that small icy bodies in the outer Solar System are inactive and incapable of sustaining atmospheres.
Researchers have proposed several possible explanations. One theory suggests the atmosphere may be generated by cryovolcanism—ice volcanoes releasing gas from the object’s interior. Another possibility is that a recent comet impact released material into space, forming a temporary atmosphere.
However, some scientists remain cautious. Jose-Luis Ortiz noted that more data is needed and suggested an alternative explanation could be a ring system around the object rather than an atmosphere.
Further observations, potentially using the James Webb Space Telescope, are expected to provide clearer answers about the nature of this distant world.
The findings also come amid renewed debate about Pluto’s classification. NASA officials, including administrator Jared Isaacman, have recently discussed the possibility of restoring Pluto’s status as a full planet. However, the discovery of similar objects with atmospheric features could complicate that argument.
If confirmed, the presence of an atmosphere on (612533) 2002 XV93 would mark a significant breakthrough in planetary science, offering new insights into the dynamic processes shaping even the most distant corners of our Solar System.
