Is the interstellar asteroid really a comet?University of Hawaiʻi at Mānoa
Astronomer, Institute for Astronomy
Roy R Gal, 808-388-8690
Associate Specialist, Institute for Astronomy
The interstellar object ʻOumuamua was discovered back on October 19, 2017, but the puzzle of its true nature has taken months to unravel, and may never be fully solved.
Meaning 'scout from the distant past' in Hawaiian, ʻOumuamua was found by astronomers working with the University of Hawaiʻi's Pan-STARRS1 survey as it came close to Earth's orbit. But what is it - an asteroid, or a comet? As soon as it was spotted, astronomers from around the world were on the case.
The first clue: its trajectory. Extensive follow-up observations by the Canada-France-Hawaiʻi Telescope (CFHT), the European Space Agency's (ESA) Optical Ground Station telescope in Tenerife, Canary Islands, and other telescopes around the world have helped pin it down.
ʻOumuamua was first spotted about a month after its closest approach to the Sun, which took it within the orbit of Mercury. Unlike any asteroid or comet observed before, this new object sped past the Sun, approaching from 'above' the plabe of the planets on a highly inclined orbit, moving fast enough (70,800 miles per hour as of July 1, 2018) to escape the Sun's gravitational pull and eventually depart our Solar System.
Initially, astronomers assumed ʻOumuamua was a comet. Current understanding of planet formation predicts more interstellar comets than interstellar asteroids. However, astronomers did not see evidence of gas emission or a dusty environment in the observations. Without these hallmarks of cometary activity, it was classified as the first interstellar asteroid.
But the story has another surprising twist.
Following the initial discovery observations with Pan-STARRS, a team of astronomers led by Marco Micheli of ESA's SSA-NEO Coordination Centre, and Karen Meech of the University of Hawaiʻi Institute for Astronomy, continued to make high precision measurements of the object and its position using many ground-based facilities like CFHT, as well as the Hubble Space Telescope. The final images were taken with Hubble in January, before the object became too faint to observe as it sped away on its outbound orbit.
Contrary to their expectations, the team found that the object was not following the anticipated trajectory if only the gravity of the Sun and the planets were determining its path. "Unexpectedly, we found that ʻOumuamua was not slowing down as much as it should have due to just gravitational forces", says Marco, lead author of the paper reporting the team's findings, published today in the journal Nature. What could be causing this curious behavior?
Rigorous analysis ruled out a range of possible influences, such as radiation pressure or thermal effects from the Sun, or interaction with the Sun's solar wind. Other, less likely scenarios, such as a collision with another body, or ʻOumuamua being two separate, loosely held-together objects, were also discarded.
Comets contain ices that sublimate, or turn directly from a solid to a gas, when warmed by the Sun. This process drags out dust from the comet's surface to create a fuzzy 'atmosphere' and sometimes a tail. The release of gas pressure at different locations and times can have the effect of pushing the comet slightly off-course compared with the expected path if only gravitational forces were at play.
"Thanks to the high quality of the observations we were able to characterize the direction and magnitude of the non-gravitational perturbation, which behaves the same way as comet outgassing," says Davide Farnocchia of NASA's Jet Propulsion Laboratory.
The team has not detected any dusty material or chemical signatures that would typically characterize a comet, even in the deepest images from ESO's Very Large Telescope, Hubble, and the Gemini South telescope. "ʻOumuamua is small - no more than a half a mile long - and it could have been releasing a small amount of relatively large dust for it to have escaped detection," said Meech. "To really understand ʻOumuamua we would need to send a space probe to it. This is actually possible, but it would be very expensive and take a long time to get there, so it isn't practical this time. We just have to be ready for the next one."
"It was extremely surprising that ʻOumuamua first appeared as an asteroid, given that we expect interstellar comets should be far more abundant, so we have at least solved that particular puzzle," says Olivier Hainaut of the European Southern Observatory. "It is still a tiny and weird object that is not behaving like a typical comet, but our results certainly lean towards it being a comet and not an asteroid after all."
Because of its small size and faintness, current observations of ʻOumuamua do not provide all the information astronomers need to determine important aspects of the comet's surface. "When ʻOumuamua was discovered, the astronomy community gathered as much data as possible, but ultimately, the object was just not visible long enough to answer all our questions," says Ken Chambers from Pan-STARRS. "With Pan-STARRS monitoring the skies, we hope to discover more ʻOumuamua-like objects in the future and begin to answer the really interesting questions about this class of objects."
* * *
To view full captions and download images and an animation of ʻOumuamua, go to http://www.ifa.hawaii.edu/info/press-releases/Oumuamua-06-2018/.
Additional Information & Companion Press Releases:
The research team's work is presented in the scientific paper "Non-gravitational acceleration in the trajectory of 1I/2017 U1 (ʻOumuamua)", which is published in the journal Nature on 27 June 2018.
The international team of astronomers in this study consists of Marco Micheli (European Space Agency & INAF, Italy), Davide Farnocchia (NASA Jet Propulsion Laboratory, USA), Karen J. Meech (University of Hawaii Institute for Astronomy, USA), Marc W. Buie (Southwest Research Institute, USA), Olivier R. Hainaut (European Southern Observatory, Germany), Dina Prialnik (Tel Aviv University School of Geosciences, Israel), Harold A. Weaver (Johns Hopkins University Applied Physics Laboratory, USA), Paul W. Chodas (NASA Jet Propulsion Laboratory, USA), Jan T. Kleyna (University of Hawaii Institute for Astronomy, USA), Robert Weryk (University of Hawaii Institute for Astronomy, USA), Richard J. Wainscoat (University of Hawaii Institute for Astronomy, USA), Harald Ebeling (University of Hawaii Institute for Astronomy, USA), Jacqueline V. Keane (University of Hawaii Institute for Astronomy, USA), Kenneth C. Chambers (University of Hawaii Institute for Astronomy, USA), Detlef Koschny (European Space Agency, European Space Research and Technology Centre, & Technical University of Munich, Germany), and Anastassios E. Petropoulos (NASA Jet Propulsion Laboratory, USA).
For more information, visit: http://www.ifa.hawaii.edu/info/press-releases/Oumuamua-06-2018/