A study suggests our best chance of defending the planet from asteroids is to equip spacecraft with solar-powered lasers. The bonus is that the technology already exists.
In the cinematic world, our planet’s destruction by the impact of another cosmic body is one of the few science-fiction tropes to bridge the blockbuster (Meteor, Armageddon, Deep Impact) and the arthouse (Last Night, Melancholia). Whatever else that means, it seems to imply that we’re all thinking about it.
But how do you think about it? The impact of a 10-km (6-mile) asteroid would be apocalyptic, but the chances of it happening in the next few generations are all but negligible. The smaller the asteroid, though, the bigger the danger, as witnessed by the recent near miss of the 7-metre (23-feet) 2012 KT42, the sixth closest encounter of any known asteroid. But, Bruce Willis apart, can we even begin to think about averting such an event with today’s technologies?
This is one of those areas in which hard science can degenerate into idle speculation and fantasy. That’s why a paper, as yet unpublished, by two aerospace engineers at the University of Strathclyde in Glasgow, UK, is worth attending to. No one would claim that the plan sketched by to deflect Earth-threatening asteroids with solar-driven lasers is a blueprint for the survival of mankind, or that governments should be rushing to implement the idea. Rather, it’s the sort of ballpark calculation that lets us contemplate the magnitude of the task.
Deflection tactics
But there’s another reason to take note, which the authors don’t mention. Recent announcements of plans to – in particular the launch of backed by Larry Page and Eric Schmidt of Google and commercial spaceflight entrepreneur Peter Diamandis – has got people talking about whether some of these cosmic goldmines might be nudged closer to Earth for easier access. Any technology that could alter the course of asteroids might therefore excite more interest from private speculators than from governments wanting to prevent doomsday.
The basic idea behind this approach isn’t new. In fact it goes back to 1994, when planetary scientist Jay Melosh, a specialist on meteorite impacts, and his colleagues proposed that asteroids on a collision course with our planet might be deflected by the type of nuclear blasts favoured in Armageddon.
Another possibility makes use of a huge reflector floating near an asteroid, which could focus sunlight onto the surface and burn off a jet of icy material. According to Newton’s third this would gradually change the asteroid’s course: the momentum of the material flung out in one direction would be compensated by a change in the asteroid’s own direction of motion. Some researchers expanded the idea by proposing the use of a whole fleet of mirror-bearing spacecraft around the asteroid. But Vasile and Maddock pointed out that if the reflectors are going to be close enough to the asteroid to achieve strong solar heating, there’s a risk that the mirrors will be covered with the debris coming off the surface.
Laser blast
That’s why the duo now envisage using laser beams instead to heat the surface: they remain tightly focused over large distances, and so can be stationed further away. Lasers too have been considered before for this purpose. But they eat up a lot of energy, and previous proposals have imagined running them from a nuclear power source on a single spacecraft. In contrast, Vasile and Maddock propose using a swarm of craft – which are easier to build – equipped with modest-sized, electrically powered lasers driven by photovoltaic cells, powered in turn by light-collecting mirrors perhaps a few metres in size.
But how do you think about it? The impact of a 10-km (6-mile) asteroid would be apocalyptic, but the chances of it happening in the next few generations are all but negligible. The smaller the asteroid, though, the bigger the danger, as witnessed by the recent near miss of the 7-metre (23-feet) 2012 KT42, the sixth closest encounter of any known asteroid. But, Bruce Willis apart, can we even begin to think about averting such an event with today’s technologies?
This is one of those areas in which hard science can degenerate into idle speculation and fantasy. That’s why a paper, as yet unpublished, by two aerospace engineers at the University of Strathclyde in Glasgow, UK, is worth attending to. No one would claim that the plan sketched by to deflect Earth-threatening asteroids with solar-driven lasers is a blueprint for the survival of mankind, or that governments should be rushing to implement the idea. Rather, it’s the sort of ballpark calculation that lets us contemplate the magnitude of the task.
Deflection tactics
But there’s another reason to take note, which the authors don’t mention. Recent announcements of plans to – in particular the launch of backed by Larry Page and Eric Schmidt of Google and commercial spaceflight entrepreneur Peter Diamandis – has got people talking about whether some of these cosmic goldmines might be nudged closer to Earth for easier access. Any technology that could alter the course of asteroids might therefore excite more interest from private speculators than from governments wanting to prevent doomsday.
The basic idea behind this approach isn’t new. In fact it goes back to 1994, when planetary scientist Jay Melosh, a specialist on meteorite impacts, and his colleagues proposed that asteroids on a collision course with our planet might be deflected by the type of nuclear blasts favoured in Armageddon.
Another possibility makes use of a huge reflector floating near an asteroid, which could focus sunlight onto the surface and burn off a jet of icy material. According to Newton’s third this would gradually change the asteroid’s course: the momentum of the material flung out in one direction would be compensated by a change in the asteroid’s own direction of motion. Some researchers expanded the idea by proposing the use of a whole fleet of mirror-bearing spacecraft around the asteroid. But Vasile and Maddock pointed out that if the reflectors are going to be close enough to the asteroid to achieve strong solar heating, there’s a risk that the mirrors will be covered with the debris coming off the surface.
Laser blast
That’s why the duo now envisage using laser beams instead to heat the surface: they remain tightly focused over large distances, and so can be stationed further away. Lasers too have been considered before for this purpose. But they eat up a lot of energy, and previous proposals have imagined running them from a nuclear power source on a single spacecraft. In contrast, Vasile and Maddock propose using a swarm of craft – which are easier to build – equipped with modest-sized, electrically powered lasers driven by photovoltaic cells, powered in turn by light-collecting mirrors perhaps a few metres in size.
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