A Mission to Deflect an Asteroid Just Moved into the Final Design and Assembly Phase

Within near-Earth space, there are over 18,000 asteroids whose orbit occasionally brings them close to Earth. Over the course of millions of years, some of these Near-Earth Objects (NEOs) – which range from a few meters to tens of kilometers in diameter – may even collide with Earth. It is for this reason that the ESA and other space agencies around the world are engaged in coordinated efforts to routinely monitor larger NEOs and track their orbits.

In addition, NASA and other space agencies have been developing counter-measures in case any of these objects stray too close to our planet in the future. One proposal is NASA’s Double Asteroid Redirection Test (DART), the world’s first spacecraft specifically designed to deflect incoming asteroids. This spacecraft recently moved into the final design and assembly phase and will launch to space in the next few years.

The Double Asteroid Redirection Test (DART) was designed and built by the Johns Hopkins University Applied Physics Laboratory (JHUAPL), with support from NASA’s Jet Propulsion Laboratory (JPL), Goddard Space Flight Center (GSFC), and Johnson Space Center (JSC). This mission will test the kinetic impactor technique, which consists of striking an asteroid to shift its orbit and deflect it away from Earth – thus demonstrating our ability to protect our planet from a potential impact.

Artit’s impression of the Double Asteroid Redirection Test (DART) mission and the asteroid system Didymos. Credit: ESA/AFP

At present, the DART mission’s launch window ranges from late December 2020 to May 2021. Once it reaches space, DART will rendezvous with the binary asteroid known as Didymos (Greek for “twin”), which consists of Didymos A – which measures about 800 meters (half a mile) in diameter – and the moonlet Didymos B, which orbits A and is about 161.5 meters (530 feet) in diameter.

The DART spacecraft will be relying on the NASA Evolutionary Xenon Thruster – Commercial (NEXT-C), a solar electric propulsion (SEP) system similar to what the Dawn spacecraft used to reach the Main Asteroid Belt.  This thruster system will not only reduce the overall weight of the spacecraft (which reduces the costs of launching into space), it will also allow for a significant degree of flexibility with the mission timeline and launch window.

Once in space, DART will gradually spiral out beyond the orbit of the Moon to escape Earth’s gravitational pull and then fly towards Didymos. It will intercept Didymos B in early October 2022, when the asteroid system will be within 11 million kilometers (6.8 million mi) of Earth. At this distance, ground-based telescopes and planetary radar will be able to observe and measure the change in momentum imparted to the moonlet.

Using an onboard targeting system developed by the JHUAPL, DART will then aim itself at Didymos B and strike the smaller body at a speed of about 5.95 km/s (3.7 mps). Both the spacecraft and ground-based observatories will then verify that Didymos B has been pushed off course.

DART will launch between December 2020 and May 2021 and use the NEXT-C SEP engine to rendezvous with Didymos. Credit: NASA

As Andrew Rivkin, a who co-leads the DART investigation with the JHUAPL’s Andrew Cheng, said in a recent JHUAPL press release:

“With DART, we want to understand the nature of asteroids by seeing how a representative body reacts when impacted, with an eye toward applying that knowledge if we are faced with the need to deflect an incoming object. In addition, DART will be the first planned visit to a binary asteroid system, which is an important subset of near-Earth asteroids and one we have yet to fully understand.”

In short, this test will allow scientists from around the world to determine the effectiveness of the kinetic impact technique as an asteroid mitigation strategy. However, the most important tool when it comes to planetary defense remains the ability to track objects and issue early warnings of any potential close flybys of Earth.

The DART mission is managed by the Planetary Missions Program Office at Marshall Space Flight Center, as part of NASA’s Planetary Defense Coordination Office (PDCO). Established in 2016, the PDCO is responsible for finding, tracking and characterizing potentially hazardous asteroids and comets, issuing warnings about possible impacts, and assisting with plans for government-led responses to actual impact threats.

Further Reading: JHUAPL, NASA

Matt Williams

Matt Williams is a space journalist and science communicator for Universe Today and Interesting Engineering. He's also a science fiction author, podcaster (Stories from Space), and Taekwon-Do instructor who lives on Vancouver Island with his wife and family.

Recent Posts

Another Ghostly Spiral Galaxy Revealed by JWST

The famous American baseball player once said, "You can observe a lot just by watching."…

5 hours ago

Climate Change is Making the Skies Worse for Astronomy

Light pollution. Satellite trains and radio frequency interference. Encroaching civilization. These all pose threats to…

7 hours ago

TESS Finds a Super-Earth and two Mini-Neptunes in a Single System

A recent study based on TESS data has revealed a three-planet system (two mini-Neptunes and…

7 hours ago

This is the Last Thing DART saw as it Smashed Into its Asteroid Target

The first-ever planetary defense technology demonstration mission successfully conducted its mission, slamming into the surface…

8 hours ago

Scientists in Antarctica Have Access to Starlink Now. It’s Available on 7 Continents

SpaceX’s Starlink service is now available in Antarctica, according to a tweet from the National…

19 hours ago

Jupiter at Opposition 2022, Closest in 59 Years

Be sure to observe Jupiter this week, during its finest apparition of a lifetime.

1 day ago