An asteroid will hit Earth at some point. What can we do about it?

dinosaurs look on as an asteroid plumets through the sky
Dinosaurs look on as an asteroid plumets through the sky. (Image credit: Esteban De Armas/Shutterstock)

Any day now, it could happen: We could detect an asteroid on an Earth-crossing trajectory. It might be a small one; it might be a big one. It might be tomorrow; it might be a thousand years from now. So what can we do about it?

We know that rocks of all shapes and sizes have struck Earth pretty much since it formed. We see evidence of it on the moon: All those craters preserve a record of the damage. On our planet, craters are rarer, but that's only because wind and water erode the evidence of recent craters, and plate tectonics takes care of the older ones.

Based on evidence from cratering records and observed asteroid populations, we can put together a general picture of how often disaster befalls our world. Every few years, an object about a dozen meters across hits our planet. When it does, it releases the energy equivalent of a decent-sized nuclear bomb. But most of those detonate in the upper atmosphere over open ocean, so we don't tend to notice them.

Related: How many potentially dangerous asteroids narrowly miss Earth each year? 

On the larger end, kilometer-scale asteroids strike Earth around every 10 million years. Those have the potential to lead to global calamity — it didn't work out too well for the dinosaurs. Thankfully, while these giant space rocks are devastating, they are exceptionally rare. 

In between those extremes lies the sweet spot of danger: large asteroids that could wipe out a city or wreak havoc on a civilization — it would be, by far, the greatest catastrophe to ever happen to us. Those kinds of objects hit Earth every few thousand years. And those are the ones we need to worry about.

To track and defend 

So far, the International Astronomical Union's Minor Planet Center, which tracks these sorts of things, has counted 34,152 near-Earth objects (NEOs), which are asteroids whose orbits bring them within 0.05 astronomical units (AU) of Earth's orbit. (One AU is about 150 million kilometers, or 93 million miles — roughly the average distance between Earth and the sun.) These NEOs aren't necessarily threats — the vast majority are almost always well away from Earth — but they are definitely the ones we have to keep a close eye on.

This catalog comes from a collection of observatories on the ground and in space, usually captured on borrowed, extra time. But the upcoming Vera C. Rubin Observatory will provide a major boost to NEO detection, as it will continuously monitor the sky, providing a complete catalog every few nights. Astronomers expect that, with this observatory, we will identify between three and 10 times the current number of known NEOs.

But identifying these objects is just one piece of the puzzle. We also need to know where the asteroids are headed, which requires tracking their movements night after night. And you can't just monitor for a few nights and call it a day; asteroids have a nasty habit of frequently changing their orbits. This is due to their small, irregular size. Small gravitational tugs from the giant planets can alter their trajectories, as can close passes with each other. Even their color and shape make a difference: Depending on the asteroid's reflectivity and spin rate, the sun can unevenly heat the surface of the space rock, causing a slight but persistent shift in momentum.

It's only through rigorous, persistent monitoring that we can confidently identify any potential threat to our home.

Big guns 

That's part one of a logical planetary defense strategy. Part two is actually doing something about the threat.

One option is to do nothing: Just let the object hit Earth and hope it doesn't cause too much damage. That's not too appealing, so thankfully, we can take a more active approach.

If we spot the asteroid early enough, we can nudge it out of its current orbit. NASA demonstrated the feasibility of this approach with the success of the Double Asteroid Redirection Test (DART) mission, in which a simple spacecraft slammed headfirst into Didymos, the small moonlet of the asteroid Dimorphos. The impact triggered a measurable shift in Didymos' orbit, suggesting we might just be able to pull off this stunt in the event of a real threat.

If slamming headfirst seems a little too brutal, we can also adjust the asteroid's orbit in more subtle ways. A "gravity tractor" could send a spacecraft in orbit around an asteroid; that spacecraft would slowly change the asteroid's direction, and its gravitational influence would shift the direction of the asteroid as well. We could also paint the threatening rock, causing it to reflect a different amount of sunlight on one side, which would also change its orbit.

The key to making all of this work is early detection. If we spot the asteroid too late, then we won't be able to deliver enough energy to it to change its course. We could maybe alter where on Earth the object strikes — for example, we could attempt to aim it over the open ocean — but that's the best we could hope for.

So, when it comes to preventing the worst disaster humanity could ever see, we need to keep our eyes on the sky, patient and alert for danger.

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Paul Sutter
Space.com Contributor

Paul M. Sutter is an astrophysicist at SUNY Stony Brook and the Flatiron Institute in New York City. Paul received his PhD in Physics from the University of Illinois at Urbana-Champaign in 2011, and spent three years at the Paris Institute of Astrophysics, followed by a research fellowship in Trieste, Italy, His research focuses on many diverse topics, from the emptiest regions of the universe to the earliest moments of the Big Bang to the hunt for the first stars. As an "Agent to the Stars," Paul has passionately engaged the public in science outreach for several years. He is the host of the popular "Ask a Spaceman!" podcast, author of "Your Place in the Universe" and "How to Die in Space" and he frequently appears on TV — including on The Weather Channel, for which he serves as Official Space Specialist.

  • Questioner
    A big powerful laser beem.
    It will cause ablation of material where the asteroid is hit and will tend to push it away from that direction.
    It will require a huge solar array in cislunar space or on the moon and during its 'down' time it can beam green energy down to us on Earth.

    Easy peezy.

    (I've seen how they do it in the movies.)
    Reply
  • Atlan0001
    "What can we do about it?" Colonize outer space with millions to billions and more eyes purposely looking for them! Millions to billions and more new type asteroid 'Stone Age' "hunter-gatherers"!
    Reply
  • Classical Motion
    We are never going anywhere my friend. We are pinned here. All of your dreaming will be done here.
    Reply
  • Classical Motion
    The temptation to overcome distance is an illusion.
    Reply
  • Atlan0001
    Classical Motion said:
    The temptation to overcome distance is an illusion.
    I have children, grandchildren, and great grandchildren. They inform me (a lifelong student of history among other things) in too many ways for you to understand that the future of birthing new and expanding frontiers is no different than the past of birthing new and expanding frontiers. History always repeats in large even if not in small details (noted historian Will Durant, among others).
    Reply
  • billslugg
    In a scale model, if the Sun was a golf ball, the Earth would be a mustard seed about 20 feet away. The nearest star another golf ball 736 miles away. It would take us about a year, with current technology, to reach the Sun. Figure 200,000 years to the nearest star, plus rest stops.
    Reply
  • Classical Motion
    There is earth dreaming and space dreaming. The difference is so great they can not compare. Space travel will remain fiction. If one thinks solar travel is space travel, ones needs to rethink space.

    It ain't gonna happen. But of course that statement is a challenge for many.

    But it's truly not a dare, it's simply a hard fact.

    For your great, great, great grandchildren.
    Reply
  • Atlan0001
    Classical Motion said:
    There is earth dreaming and space dreaming. The difference is so great they can not compare. Space travel will remain fiction. If one thinks solar travel is space travel, ones needs to rethink space.

    It ain't gonna happen. But of course that statement is a challenge for many.

    But it's truly not a dare, it's simply a hard fact.

    For your great, great, great grandchildren.
    You would fit in perfectly with the naysayers of all ages.
    Reply
  • Atlan0001
    billslugg said:
    In a scale model, if the Sun was a golf ball, the Earth would be a mustard seed about 20 feet away. The nearest star another golf ball 500 miles away. It would take us about a year, with current technology, to reach the Sun. Figure 100,000 years to the nearest star..
    It's a good thing you said, "current technology", Bill. A couple of hundred years ago, even less, people couldn't fly the skies, much less orbit the Earth, with their brand of "current technology."
    Reply
  • Atlan0001
    Ad #11:

    There were physics existing that the people of those times were unaware of. There are physics in and to the universe existing that we are unaware of today, regardless of those people who think we in our isolation know everything there is to know regarding physics and the universe at large . . . today!
    Reply