NASA prepares for Armageddon with a tabletop planetary defence exercise

NASA is conducting planetary defence drills to see what would happen if an apocalyptic space rock was heading straight for Earth.

Participants will discuss potential preparations for studying an asteroid or comet, as well as how to deflect it and lessen the damage caused by any impact. 

The space agency has been scanning the skies for more than 20 years, looking for what it calls Near-Earth Objects (NEOs).

NEOs are asteroids and comets that orbit the sun and come within 30 million miles (50m km) of Earth’s orbit. 

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This diagram shows the orbits of the fictional asteroid and Earth and the point at which the orbits intersect. The asteroid makes just over 3 orbits of the Sun between discovery and the possibility of an impact in 2027 

The threat of asteroid impacts has gained increasing prominence over recent years, particularly since the Chelyabinsk fireball of 2013. 

The meteor, which blazed across the southern Ural Mountain range in February 2013, was the largest recorded meteor strike in more than a century, after the Tunguska event of 1908.

More than 1,600 people were injured by the shock wave from the explosion, estimated to be as strong as 20 Hiroshima atomic bombs.

In preparation for a possible impact, NASA and other international science organisations will participate in the 2019 Planetary Defense Conference next week. 

A ‘tabletop exercise’ will play out the realistic—but fictional—scenarios for an asteroid and a comet on an impact trajectory with Earth.  

The NEO impact scenario have been developed by the NASA Jet Propulsion Laboratory’s Center for NEO Studies (CNEOS).

The asteroid scenario begins with the premise that on March 26, astronomers ‘discovered’ an asteroid that they consider is potentially hazardous to Earth.

After a ‘few months’ of tracking, observers predict that this NEO – dubbed 2019 PDC – will pass within 0.05 astronomical units (AU) of Earth.

One AU is the distance between the Earth and the sun and equates to 92,955,807 miles (149,597,871 km).

In the fictional simulation, NASA claims the asteroid poses a one in 100 chance of colliding with Earth and it may land on April 29, 2027. 

It is first located 35 million miles (57 million kilometres) from Earth and approaching at 31,000 mph (14km per second) and getting progressively brighter. 

Weeks of observation found it more and more likely it would impact Earth in 2027 but details of the asteroid’s shape, size and composition remain scarce. 

All that is known is the asteroid’s average size could be anywhere from 330 feet to 1,000 feet (100 meters to 300 meters).

More than a month after first spotted it continues to fly towards Earth and passes Earth at a distance of 0.13 au on May 13 2019. it is next expected to return close to Earth in 2027. 

The conference will pick up the event at this point and decide on the best course of action.  

Experts will discuss the dangers posed by NEOs and actions that might be taken to deflect a threatening object.  

‘These exercises have really helped us in the planetary defense community to understand what our colleagues on the disaster management side need to know,’ Lindley Johnson, NASA’s Planetary Defense Officer, said. 

‘This exercise will help us develop more effective communications with each other and with our governments.’

This diagram zooms in on the intersection point of the orbits and shows the uncertainty in the predicted position of the asteroid (red dots reveal potential spots for where the asteroid will pass Earth).  The uncertainty region is several times longer than the diameter of the Moon’s orbit but will shrink as more data is gathered on the asteroid's path and trajectory

This diagram zooms in on the intersection point of the orbits and shows the uncertainty in the predicted position of the asteroid (red dots reveal potential spots for where the asteroid will pass Earth).  The uncertainty region is several times longer than the diameter of the Moon’s orbit but will shrink as more data is gathered on the asteroid’s path and trajectory 

The risk corridor spans from Hawaii on the western end and across the US and Atlantic Ocean (pictured)

The risk corridor reaches as far as  central and southern Africa on the eastern end (pictured)

Intersection of the uncertainty region with the Earth creates a’risk corridor’ across the surface of the Earth. The corridor wraps more than halfway around the globe (pictured, red dots are potential landing locations) on the risk corridor

NASA is conducting planetary defence drills to see what would happen if an apocalyptic asteroid was heading straight for Earth. The Manicouagan impact crater in Quebec, Canada (circled right), is one of our many reminders that asteroids have impacted Earth

NASA is conducting planetary defence drills to see what would happen if an apocalyptic asteroid was heading straight for Earth. The Manicouagan impact crater in Quebec, Canada (circled right), is one of our many reminders that asteroids have impacted Earth

The conference will also discuss a hypothetical comet impact scenario. 

This fictional event states a comet was spotted on April 4 2019 and could collide with Earth on February 28, 2021. 

It has an orbital period believed to be several thousand years and astronomers speculate that its core is possibly only about 0.62 miles (1 kilometre) in size.   

NASA has in recent weeks announced measures it hopes will help to combat the threat posed by by NEOs. 

The conference will also discuss a hypothetical comet impact scenario. This fictional event states a comet was spotted on April 4 2019 and could collide with Earth on February 28, 2021. It has an orbital period believed to be several thousand years

The conference will also discuss a hypothetical comet impact scenario. This fictional event states a comet was spotted on April 4 2019 and could collide with Earth on February 28, 2021. It has an orbital period believed to be several thousand years

Astronomers speculate that its core is possibly only about 0.62 miles (1 kilometre) in size and could his any of the red dots on this map.  NASA has in recent weeks announced measures it hopes will help to combat the threat posed by by NEOs

Astronomers speculate that its core is possibly only about 0.62 miles (1 kilometre) in size and could his any of the red dots on this map.  NASA has in recent weeks announced measures it hopes will help to combat the threat posed by by NEOs

On April 11, the space agency announced that its radical mission to fire a small spacecraft directly into an asteroid now has SpaceX on the roster, too.

It selected Elon Musk‘s aerospace company to launch its Double Asteroid Redirection Test (DART) mission, which is slated to lift off in June 2021.

The groundbreaking mission will be the first demonstrated attempt to deflect an asteroid by purposely crashing an object into it at high speed.

After launching from California‘s Vandenberg Air Force base atop a Falcon 9 rocket in 2021, the DART craft is expected to reach the object Didymos in October 2022, when it’s 6.8 million miles (11m km) from Earth.

The DART mission relies on what’s known as a ‘kinetic impactor’ – in this case an eight foot long (2.4m) craft with solar electric propulsion.

DART will be targeting the binary near-Earth asteroid Didymos, which measures roughly 2,600 feet (800m) across.

NASA has in recent weeks announced measures it hopes will help to combat the threat posed by by NEOs. The DART mission relies on what’s known as a ‘kinetic impactor’ targeting the binary near-Earth asteroid Didymos (artist's impression)

NASA has in recent weeks announced measures it hopes will help to combat the threat posed by by NEOs. The DART mission relies on what’s known as a ‘kinetic impactor’ targeting the binary near-Earth asteroid Didymos (artist’s impression)

After launching from California’s Vandenberg Air Force base atop a Falcon 9 rocket in 2021, the DART craft is expected to reach the object Didymos in October 2022, when it’s 6.8 million miles from Earth. File photo of a Falcon 9 after launch

After launching from California’s Vandenberg Air Force base atop a Falcon 9 rocket in 2021, the DART craft is expected to reach the object Didymos in October 2022, when it’s 6.8 million miles from Earth. File photo of a Falcon 9 after launch

WHAT COULD WE DO TO STOP AN ASTEROID COLLIDING WITH EARTH?

Currently Nasa would not be able to deflect an asteroid if it were heading for Earth but it could mitigate the impact and take measures that would protect lives and property.

This would include evacuating the impact area and moving key infrastructure.

Finding out about the orbit trajectory, size, shape, mass, composition and rotational dynamics would help experts determine the severity of a potential impact.

However, the key to mitigating damage is to find any potential threat as early as possible.

Nasa is currently moving forward with a refrigerator-sized spacecraft capable of preventing asteroids from colliding with Earth. A test with a small, nonthreatening asteroid is planned for 2024.

This is the first-ever mission to demonstrate an asteroid deflection technique for planetary defence.

The Double Asteroid Redirection Test (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 top NASA asteroid scientist also recently said that the best way to defend the Earth from asteroids is to build a new telescope capable of spotting them as soon as possible.  

Dr Amy Mainzer from NASA’s Jet Propulsion Laboratory in Pasadena, California, said that trying to spot asteroids with current telescopes was like trying to spot a ‘lump of coal in the night’s sky’. 

In April 2019, her team proposed a new system designed to spot large meteors capable of causing significant damage.  

It would identify incoming asteroids capable of causing huge loss of life – just like the meteor which wiped out the dinosaurs 66 million years ago. 

They claim this would give the scientists more time to come up with a strategy to intercept the rock. 

A NASA scientist has said that to defend the Earth from dangerous asteroids is to detect them via heat using an infra-red telescope called the Near-Earth Object Camera (NEOCam). Comet Catalina (pictured) in 2015 was captured by such a telescope called  NEOWISE

A NASA scientist has said that to defend the Earth from dangerous asteroids is to detect them via heat using an infra-red telescope called the Near-Earth Object Camera (NEOCam). Comet Catalina (pictured) in 2015 was captured by such a telescope called  NEOWISE

Dr Amy Mainzer said that trying to spot asteroids via their 'faint' light was like trying to spot a 'lump of coal in the night's sky', but that a proposed Near-Earth Object Camera mission (pictured) that detects heat waves would make it a lot more accurate

Dr Amy Mainzer said that trying to spot asteroids via their ‘faint’ light was like trying to spot a ‘lump of coal in the night’s sky’, but that a proposed Near-Earth Object Camera mission (pictured) that detects heat waves would make it a lot more accurate

Incoming space rocks are not always spotted in advance of their arrival, however.

Incredible images released in March 2019 revealed a meteor that exploded in the Earth’s atmosphere in December with ten times the force of the Hiroshima bomb – yet no one detected it. 

The incident took place at 11:50pm GMT (3:30am EST) on December 18, 2018, over the Bering Sea – between Russia and Alaska – but has only just been discovered.

It is believed to be the second largest meteor explosion in the last 30 years, and the biggest since the high-profile Chelyabinsk incident.