NASA plans to test asteroid deflection technique designed to prevent Earth impact

NASA is moving forward with a plan to develop a refrigerator-sized spacecraft capable of deflecting asteroids and preventing them from colliding with Earth.

The Double Asteroid Redirection Test, or DART, is being designed and would be built and managed by scientists at the Johns Hopkins Applied Physics Laboratory. NASA approved a move from concept development to the preliminary design phase on June 23.

DART would use what is known as a kinetic impactor technique—striking the asteroid to shift its orbit. The impact would change the speed of a threatening asteroid by a small fraction of its total velocity, but by doing so well before the predicted impact, this small nudge will add up over time to a big shift of the asteroid’s path away from Earth.

A test with a small, nonthreatening asteroid is planned for 2024.

“DART is a critical step in demonstrating we can protect our planet from a future asteroid impact,” said Andy Cheng, who is co-leading the DART investigation at APL along with Andy Rivkin. “Since we don’t know that much about their internal structure or composition, we need to perform this experiment on a real asteroid. With DART, we can show how to protect Earth from an asteroid strike with a kinetic impactor by knocking the hazardous object into a different flight path that would not threaten the planet.”

Small asteroids hit Earth almost daily, breaking up harmlessly in the upper atmosphere. Objects large enough to do damage at the surface are much rarer.

The target for DART’s first test is an asteroid that will have a distant approach to Earth in October 2022, and then again in 2024. The asteroid is called Didymos—Greek for “twin”—because it’s an asteroid binary system that consists of two bodies: Didymos A, about one-half mile in size; and a smaller asteroid orbiting it called Didymos B, about 530 feet in size. DART would impact only the smaller of the two bodies, Didymos B.

The Didymos system has been closely studied since 2003. The primary body is a rocky S-type object, with composition similar to that of many asteroids. The composition of its small companion, Didymos B, is unknown, but the size is typical of asteroids that could potentially create regional effects should they impact Earth.

After launch, DART would fly to Didymos and use an APL-developed onboard autonomous targeting system to aim itself at Didymos B. Then the spacecraft would strike the smaller body at a speed about nine times faster than a bullet, approximately 3.7 miles per second. Earth-based observatories would be able to see the impact and the resulting change in the orbit of Didymos B around Didymos A, allowing scientists to better determine the capabilities of kinetic impact as an asteroid mitigation strategy.

Objects larger than 0.6 miles in diameter—large enough to cause global effects—have been the focus of NASA’s ground-based search for potentially hazardous objects with orbits that bring them near the Earth. About 93 percent of these sized objects have already been found, NASA says.

DART would test technologies to deflect objects in the intermediate size range—large enough to do regional damage yet small enough that there are many more that have not been observed and could someday hit Earth. NASA-funded telescopes and other assets continue to search for these objects, track their orbits, and determine if they are a threat.

To assess and formulate capabilities to address these potential threats, NASA in 2016 established its Planetary Defense Coordination Office, which is responsible for finding, tracking, and characterizing potentially hazardous asteroids and comets coming near Earth; issuing warnings about possible impacts; and assisting plans and coordination of U.S. government response to an actual impact threat.


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1 thought on “NASA plans to test asteroid deflection technique designed to prevent Earth impact”

  1. This will work fine, I suppose so long as the composition of the asteroid is such that it will withstand an impact. Many of them are just agglomerations of marble sized pieces. If you hit that, it will just become a collection of pieces with the same orbit. Oops.

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