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Busting Earth-Bound Asteroids a Bigger Job Than We Thought

A new model suggests smashing killer space rocks with insufficient force could let gravity pull the pieces back together. Christopher Intagliata reports. 

Science, Quickly

In the movie Armageddon, an asteroid the size of Texas is hurtling toward Earth. All seems lost, but then Bruce Willis sacrifices his own life to detonate a thermonuclear bomb on the asteroid. Then you hear this from mission control: <"The two halves are going to miss us by 400 miles, and most of the small particles have been vaporized!">

Breaking a rock that big into two halves, that somehow miraculously dodge the Earth? A bit of Hollywood magic. But scientists are studying what would really happen in such a scenario.

"A big part of what we do is looking at how things break. Smashing things together and what happens after that." Charles El Mir is a mechanical engineer who studies planetary science at Johns Hopkins University. 


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He and his colleagues modeled what might happen if you smashed up a 15-mile-wide asteroid made of basalt. They started by assuming the asteroid has some tiny cracks already running through it, based on studies of real rock. Then, they struck the hypothetical space rock with another, smaller rock—just a mile wide—hurtling toward the asteroid at more than 11,000 miles per hour. When they hit, they tracked how stress waves propagated through the larger asteroid, and expanded the network of cracks. 

Previous impact models predicted that an impact like that would completely pulverize the asteroid, basically turning it to sand. But not this new model. "What we're seeing, after the impact you have this big chunk of rock that was still held together, still not completely broken down, and this piece of rock creates its own gravitational field which attracts the particles that were ejected from it, and they start re-accumulating over it." 

The scientists describe the model in the journal Icarus. [Charles El Mir et al., A new hybrid framework for simulating hypervelocity asteroid impacts and gravitational reaccumulation]

The work suggests asteroids might actually be harder to smash than we thought, meaning: "We might need to have a faster impactor, or larger mass of impactor coming in, to be able to deflect it efficiently."

In 2022 NASA's Double Asteroid Redirection Test mission, or DART, will attempt to put all this knowledge to the test, by shoving a near-Earth asteroid off its path. No Bruce Willis required.

—Christopher Intagliata

[The above text is a transcript of this podcast.]

Busting Earth-Bound Asteroids a Bigger Job Than We Thought