November 23, 2024

Cracking the ’Oumuamua Code: Alien Spaceship or Natural Phenomenon?

This artists impression shows the first interstellar item found in the Solar System, 1I/ Oumuamua, discovered in 2017. The wayward object swung within 24 million miles of the Sun prior to racing out of the planetary system. Credit: ESA/Hubble, NASA, ESO, M. Kornmesser
2017 comets unusual acceleration discussed by hydrogen outgassing from ice.
In 2017, a mysterious comet called Oumuamua fired the creativities of scientists and the public alike. It was the first known visitor from outdoors our planetary system, it had no bright coma or dust tail, like most comets, and a strange shape– something in between a cigar and a pancake– and its small size more befitted an asteroid than a comet.
But the fact that it was speeding up away from the sun in a method that astronomers might not discuss perplexed researchers, leading some to recommend that it was an alien spaceship.
Now, a University of California, Berkeley, astrochemist and a Cornell University astronomer argue that the comets mystical deviations from a hyperbolic path around the sun can be described by a simple physical mechanism most likely common among numerous icy comets: outgassing of hydrogen as the comet heated up in the sunshine.

What made Oumuamua various from every other well-studied comet in our solar system was its size: It was so little that its gravitational deflection around the sun was somewhat modified by the small push created when hydrogen gas spurted out of the ice.
A lot of comets are basically dirty snowballs that regularly approach the sun from the outer reaches of our planetary system. When warmed by sunlight, a comet ejects water and other particles, producing a brilliant halo or coma around it and typically tails of gas and dust. The ejected gases act like the thrusters on a spacecraft to give the comet a small kick that changes its trajectory a little from the elliptical orbits normal of other solar system objects, such as planets and asteroids.
An artists representation of the interstellar comet Oumuamua, as it warmed up in its method to the sun and outgassed hydrogen (white mist), which somewhat changed its orbit. The comet, which is probably pancake-shaped, is the first known item aside from dust grains to visit our planetary system from another star. Credit: NASA, ESA, Joseph Olmsted (STScI), Frank Summers (STScI).
When found, Oumuamua had no coma or tail and was too little and too far from the sun to record sufficient energy to eject much water, which led astronomers to hypothesize hugely about its structure and what was pushing it outside. Was it a hydrogen iceberg outgassing H2?
Jennifer Bergner, a UC Berkeley assistant professor of chemistry who studies the chain reactions that occur on icy rocks in the cold vacuum of area, believed there may be a simpler explanation. She brought up the subject with a colleague, Darryl Seligman, now a National Science Foundation postdoctoral fellow at Cornell University, and they chose to interact to evaluate it.
” A comet taking a trip through the interstellar medium essentially is getting prepared by cosmic radiation, forming hydrogen as an outcome. “Could that quantitatively produce the force that you require to describe the non-gravitational acceleration?”.
Remarkably, she found that experimental research published in the 1970s, 80, 90s and s showed that when ice is struck by high-energy particles akin to cosmic rays, molecular hydrogen (H2) is abundantly produced and caught within the ice. In reality, cosmic rays can penetrate 10s of meters into ice, transforming a quarter or more of the water to hydrogen gas.
” For a comet several kilometers across, the outgassing would be from a really thin shell relative to the bulk of the things, so both compositionally and in terms of any velocity, you wouldnt always expect that to be a noticeable result,” she said. “But because Oumuamua was so small, we think that it in fact produced sufficient force to power this velocity.”.
The comet, which was somewhat reddish, is believed to have been approximately 115 by 111 by 19 meters in size. While the relative dimensions were relatively particular, however, astronomers couldnt ensure the actual size because it was too small and remote for telescopes to solve. The size had actually to be approximated from the comets brightness and how the brightness altered as the comet toppled. To date, all the comets observed in our solar system– the short-period comets stemming in the Kuiper belt and the long-period comets from the more remote Oort cloud– have actually ranged from around 1 kilometer to numerous kilometers throughout.
” Whats lovely about Jennys idea is that its exactly what need to happen to interstellar comets,” Seligman stated. “We had all these silly concepts, like hydrogen icebergs and other crazy things, and its just the most generic description.”.
Bergner and Seligman will publish their conclusions today in the journal Nature. Both were postdoctoral fellows at the University of Chicago when they started working together on the paper.
Messenger from afar.
Comets are icy rocks left over from the development of the planetary system 4.5 billion years earlier, so they can inform astronomers about the conditions that existed when our solar system formed. Interstellar comets can also provide hints to the conditions around other stars surrounded by planet-forming disks.
” Comets protect a photo of what the solar system appeared like when it remained in the phase of advancement that protoplanetary disks are now,” Bergner stated. “Studying them is a way to recall at what our planetary system used to appear like in the early formation stage.”.
Jennifer Bergner in her Ph.D. lab at Harvard University. In the background is instrumentation for studying ice chemistry at the freezing temperatures particular of interstellar space. Credit: Luke Kelley.
Faraway planetary systems also seem to have comets, and lots of are likely to be ejected since of gravitational interactions with other objects in the system, which astronomers understand occurred over the history of our solar system. A few of these rogue comets must occasionally enter our solar system, providing a chance to learn more about planet development in other systems.
” The comets and asteroids in the solar system have perhaps taught us more about world development than what weve gained from the real planets in the solar system,” Seligman stated. “I think that the interstellar comets might arguably tell us more about extrasolar worlds than the extrasolar worlds we are trying to get measurements of today.”.
In the past, astronomers released numerous papers about what we can gain from the failure to observe any interstellar comets in our solar system.
Oumuamua came along.
On Oct. 19, 2017, on the island of Maui, astronomers utilizing the Pan-STARRS1 telescope, which is run by the Institute for Astronomy at the University of Hawaii in Manoa, first noticed what they believed was either a comet or an asteroid. Once they realized that its tilted orbit and high speed– 87 kilometers per 2nd– indicated that it came from outdoors our solar system, they gave it the name 1I/ Oumuamua (oh MOO-uh MOO-uh), which is Hawaiian for “a messenger from afar getting here first.” It was the first interstellar item aside from dust grains ever seen in our planetary system. A second, 2I/Borisov, was found in 2019, though it looked and behaved more like a normal comet.
As increasingly more telescopes concentrated on Oumuamua, the astronomers had the ability to chart its orbit and figure out that it had already looped around the sun and was gone out of the planetary system.
Since Oumuamuas brightness altered occasionally by a factor of 12 and varied asymmetrically, it was assumed to be extremely elongated and toppling end over end. Astronomers likewise noticed a slight acceleration far from the sun bigger than seen for asteroids and more quality of comets. When comets approach the sun, the water and gases ejected from the surface area produce a glowing, gaseous coma and release dust at the same time. Typically, dust left in the comets wake ends up being noticeable as one tail, while vapor and dust pushed by light pressure from solar rays produces a 2nd tail pointing away from the sun, plus a little inertial push outside. Other substances, such as entrapped natural products and carbon monoxide gas, also can be released.
Why was it speeding up?
Astronomers might identify no coma, outgassed particles or dust around Oumuamua. In addition, calculations showed that the solar energy hitting the comet would be insufficient to sublimate water or natural substances from its surface area to offer it the observed non-gravitational kick. Only hypervolatile gases such as H2, carbon or n2 monoxide (CO) could supply adequate acceleration to match observations, provided the incoming solar power.
” We had never ever seen a comet in the planetary system that didnt have a dust coma. The non-gravitational acceleration truly was odd,” Seligman stated.
This resulted in much speculation about what unpredictable molecules might be in the comet to cause the velocity. Seligman himself released a paper arguing that if the comet was composed of strong hydrogen– a hydrogen iceberg– it would outgas adequate hydrogen in the heat of the sun to explain the strange acceleration. Under the ideal conditions, a comet composed of strong nitrogen or solid carbon monoxide would also outgas with adequate force to affect the comets orbit.
However astronomers had to extend to discuss what conditions might result in the development of strong bodies of hydrogen or nitrogen, which have never ever been observed prior to. And how could a strong H2 body endure for perhaps 100 million years in interstellar space?
Bergner believed that outgassing of hydrogen allured in ice might be adequate to accelerate Oumuamua. As both an experimentalist and a theoretician, she studies the interaction of very cold ice– cooled to 5 or 10 degrees Kelvin, the temperature level of the interstellar medium (ISM)– with the type of energetic particles and radiation discovered in the ISM.
In searching through past publications, she found numerous experiments demonstrating that high-energy electrons, protons and heavier atoms might convert water ice into molecular hydrogen, and that the fluffy, snowball structure of a comet could entrap the gas in bubbles within the ice. Experiments revealed that when warmed, as by the heat of the sun, the ice anneals– modifications from an amorphous to a crystal structure– and forces the bubbles out, releasing the hydrogen gas. Ice at the surface of a comet, Bergner and Seligman determined, might produce sufficient gas, either in a collimated beam or fan-shaped spray, to impact the orbit of a little comet like Oumuamua.
” The main takeaway is that Oumuamua follows being a basic interstellar comet that just experienced heavy processing,” Bergner stated. “The models we ran are consistent with what we see in the planetary system from comets and asteroids. So, you could essentially begin with something that appears like a comet and have this scenario work.”.
The idea also explains the lack of a dust coma.
” Even if there was dust in the ice matrix, youre not sublimating the ice, youre just reorganizing the ice and after that letting H2 get launched. The dust isnt even going to come out,” Seligman stated.
Dark comets.
Seligman stated that their conclusion about the source of Oumuamuas velocity need to close the book on the comet. Because 2017, he, Bergner and their coworkers have recognized 6 other little comets without any observable coma, however with small non-gravitational velocities, suggesting that such “dark” comets prevail. While H2 is not most likely accountable for the accelerations of dark comets, Bergner noted, together with Oumuamua they expose that there is much to be found out about the nature of little bodies in the planetary system.
One of these dark comets, 1998 KY26, is the next target for Japans Hayabusa2 objective, which recently collected samples from the asteroid Ryugu. The 1998 KY26 was believed to be an asteroid till it was determined as a dark comet in December.
“Between discovering other dark comets in the solar system and Jennys awesome idea, I believe its got to be appropriate. Water is the most abundant part of comets in the solar system and likely in extrasolar systems.
Since H2 should form in any ice-rich body exposed to energetic radiation, the researchers suspect that the very same system would be at operate in sun-approaching comets from the Oort cloud at the external reaches of the planetary system, where comets are irradiated by cosmic rays, similar to an interstellar comet would be. Future observations of hydrogen outgassing from long-period comets could be utilized to test the situation of H2 formation and entrapment.
Numerous more interstellar and dark comets must be found by the Rubin Observatory Legacy Survey of Space and Time (LSST), allowing astronomers to figure out if hydrogen outgassing prevails in comets. Seligman has determined that the survey, which will be carried out at the Vera C. Rubin Observatory in Chile and is set to end up being functional in early 2025, must detect between one and three interstellar comets like Oumuamua every year, and likely much more that have a telltale coma, like Borisov.
Reference: “Acceleration of 1I/ Oumuamua from radiolytically produced H2 in H2O ice” by Jennifer B. Bergner and Darryl Z. Seligman, 22 March 2023, Nature.DOI: 10.1038/ s41586-022-05687-w.
Bergner was supported by a NASA Hubble Fellowship grant. Seligman was supported by the National Science Foundation (AST-17152) and NASA (80NSSC19K0444, NNX17AL71A).

The size had actually to be estimated from the comets brightness and how the brightness altered as the comet toppled. To date, all the comets observed in our solar system– the short-period comets stemming in the Kuiper belt and the long-period comets from the more distant Oort cloud– have actually varied from around 1 kilometer to hundreds of kilometers across.
Under the best conditions, a comet composed of strong nitrogen or solid carbon monoxide would also outgas with enough force to impact the comets orbit.
Ice at the surface of a comet, Bergner and Seligman determined, could release adequate gas, either in a parallelled beam or fan-shaped spray, to affect the orbit of a small comet like Oumuamua.
Since 2017, he, Bergner and their colleagues have identified 6 other little comets with no observable coma, however with small non-gravitational velocities, suggesting that such “dark” comets are common.