Sixty-five million years ago, disaster struck the Earth. An asteroid or comet around 10 km in diameter slammed into
what is now the Yucatan Peninsula in Mexico. While the idea was
ridiculed at first, this event is now widely believed to be the reason
the dinosaurs became extinct.
This realisation led to a rallying of scientists and engineers around
the world to detect and monitor the asteroids in the heavens, and if
need be, to be prepared to deflect one from hitting us.
Today, we have a Planetary Defense Coordination Office under NASA whose sole mission is to prepare us for this unlikely but devastating possibility.
It is believed that we have found all of the asteroids the size of that which killed the dinosaurs (at least those near Earth).
Recent impacts
But there are many smaller asteroids that can still do a lot of damage which are undetected. In 1908, the Tunguska event flattened about 2,000 square kilometres of forest in Siberia.
This asteroid was only about 50 metres across, but we have only found about 1 percent of the near Earth objects (NEOs) of this size.
Despite being so rare, if a large asteroid did hit Earth, it would
cause extraordinary damage. In fact, you’re more likely to be killed by
an asteroid than die in a shark attack.
We know about a number of recent asteroid impacts,
but we’re still discovering more in the geological record. Currently
it’s estimated that NEOs which can cause global ecological effects occur
around once every 500,000 years.
Right now, despite being able to detect and track large asteroids
(you can look at current known asteroid positions yourself using online databases), we know very little about their interior.
Much of what we do know is based on meteorite samples which have
fallen to Earth. But it is difficult to extrapolate small samples to
understanding what asteroids look like as a whole.
Asteroid types
Asteroids have several types based on mineral composition, but their internal structure can also potentially take several forms.
Some might be rubble piles, weakly held together by gravity and
electrostatic forces, while others might be solid bodies of rock.
Different structural types would require different methods of deflection.
For example, a rubble pile might break up if we hit it with an
object, with each smaller piece still posing a threat. This might
dictate a more finessed approach, such as hitting it with a smart cloud of smaller particles released by a space craft.
The use of explosive devices to move an asteroid is expected to be about 100 times less efficient on porous asteroids compared to more solid bodies.
Inside an asteroid
My research involves repurposing geophysical techniques used for more
than a century on Earth to determine the strength and structure of
asteroids. To test whether these techniques will work requires
simulating asteroid conditions in a lab.
This means we have to recreate the gravity, atmospheric and
temperature conditions. We also have to find a material that matches the
properties of an asteroid surface to test our equipment on.
NASA performs experiments in low gravity using a parabolic jet, which is temporarily in free fall. Atmospheric conditions can be modified in a vacuum chamber.
Researchers have developed simulant materials
that are similar in chemical composition to various classes of
asteroids. As well as being useful for testing mining equipment that
might be used on asteroids, they can also be used to test geophysical
equipment might be able to determine useful properties, such as
structure.
Once this technology is proven, it can potentially be used to land on
an asteroid and peer into its interior. By understanding its structure,
porosity and strength, we can then start to plan deflection strategies
for individual asteroids, and for asteroids in general.
Being prepared
The dinosaurs went extinct because they didn’t have a space program.
Luckily, we are more prepared (although Australia is still one of just
two OECD nations without a space program, the other is Iceland).
If we were to detect an inbound asteroid with warning of at least
several years, we can send a mission to find out what it’s made of. Then
we can plan the optimal strategy complete with backup plans.
In 1995, a workshop with ex-Cold War US and Russian weapons designers
was held to propose a way of deflecting an asteroid if it was detected
at the last minute. They came up with (though never built) a nuclear
weapon capable of instantly vaporising a 1 km asteroid.
It would also have the potential to move an extinction class asteroid
out of our path given at least a few months notice, or a comet given
two years notice. Given any less time, we may have to be content with
evacuating as many people as possible from the predicted landing site.
Asteroid impacts aren’t the only event that might wipe us out.
Nuclear warfare, biological terrorism and artificial intelligence all
have the potential to destroy us. Some researchers have even suggested that the probability of humanity surviving until 2100 is just one in two.
Given this level of risk, one thing is certain: we can and should spend more time and resources trying to reduce these risks.
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