Scientists continue to look at the results of NASA’s amazingly successful DART test to deflect a harmless asteroid. As the latest results indicate, the recoil from the explosion of debris emitted by Dimorphos after the impact was significant, adding to the spacecraft’s impact on the asteroid.
A NASA spacecraft the size of a refrigerator smash At the 535-foot (163-meter) Dimorphus on Sept. 26, Shortening its orbit around its larger partnerDidymus, with an impressive time of 33 minutes. This is equivalent to dozens of feet, which indicates the feasibility using kinetic colliders as a means of deflecting threatening asteroids.
An amazing side effect of the test was… Giant and complex columns that emanated from the asteroid after the collision. The Didymos-Dimorphos system, located 7 million miles (11 million kilometers) from Earth, even grew a long tail in the experiment’s wake. DART, short for the Double Asteroid Redirection Test, had a profound effect on Dimorphos, releasing a surprising amount of debris, or “projectiles” in the parlance of planetary scientists.
Dimorphos, as we’ve learned, is an asteroid pile of rubble, as opposed to a rocky, dense, tightly packed body. This undoubtedly contributed to the increase in the amount of debris ejected, but scientists weren’t quite sure how much debris the asteroid had thrown up as a result of the impact. preliminary the findings A presentation Thursday at the American Geophysical Union fall meeting in Chicago sheds new light on this and other aspects of the DART mission.
Not only did DART fire tons of projectiles, but it also created a ricocheting effect that propelled the asteroid in the desired direction, Andy Rifkin, lead of the DART investigation team, explained at the meeting. “We get a lot of bang for the buck,” he said Tell BBC News.
In fact, had Dimorphos had a more compact body, the same level of recoil probably wouldn’t have occurred. “If you shoot material off target, you have a kickback force,” explained DART mission scientist Andy Cheng of the Johns Hopkins University Applied Physics Laboratory, who also spoke at the meeting. The resulting bounce is similar to letting go of a balloon. As the air rushes out, it pushes the balloon in the opposite direction. In the case of Dimorphos, the ejecta stream was the air leaving the balloon, which similarly propelled the asteroid in the opposite direction.
Planetary scientists are beginning to get a sense of how much debris has been displaced. DART, which was traveling at 14,000 mph (22,500 km/h), struck hard enough to spill over two million pounds of material into the void. NASA said that’s enough to fill about six or seven rail cars statement. That estimate may actually be low, Rifkin said at the meeting, and the real number could be 10 times higher.
The scientists set the DART’s momentum factor, known as “beta,” to a value of 3.6, which means that the momentum imparted to Dimorphos was 3.6 times greater than a collision event that did not result in an ejected plume. “The result of that recoil force is that you put more momentum into the target and you end up with a bigger deflection,” Cheng told reporters. “If you’re trying to save the Earth, it makes a huge difference.”
That’s a good point, because those values would set the criteria for an actual mission to legitimately deflect a dangerous asteroid. Cheng and his colleagues will now use these results to infer beta values for other asteroids, a task that will require a deeper understanding of the object’s density, composition, porosity, and other parameters. Scientists also hope to find out the degree to which DART’s first strike moved the asteroid and how much it moved due to the bounce.
The tweeters also produced another shape—a long tail, or output shaft, that formed in the aftermath of the impact. According to Rifkin, Dimorphos sprouted a tail 18,600 miles (30,000 km) long.
“The asteroid impact was just the beginning,” said Tom Statler, DART program scientist and presenter at the meeting, in the statement. “Now we’re using the observations to study what these objects are made of and how they formed — as well as how to defend our planet in the event of an asteroid heading our way.”
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