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Deflecting asteroids is only one thing on humanity’s worry list
The writer is a science commentator
It was, literally, a striking achievement. In the early hours of Tuesday, a Nasa spacecraft slammed into a small asteroid 11mn km from Earth, its second-by-second odyssey into oblivion captured on camera and livestreamed to a world audience.
The impact was meant to shunt the rock, Dimorphos — one half of a two-asteroid binary system — into a slightly tighter orbit around its bigger partner, Didymos. The orbital tweak is yet to be confirmed but, if successful, it will demonstrate that, in principle at least, humans have the knowhow to deflect asteroids heading our way.
“What amazed and delighted me was that everything worked so well,” said Professor Alan Fitzsimmons, an astrophysicist at Queen’s University Belfast, who will now analyse images of the impact gathered from telescopes in South Africa, Chile and Hawaii and is involved in a 2027 follow-up European Space Agency mission to the same asteroid.
While it could take months to see if the orbital period has shifted by seconds or minutes, Fitzsimmons added, “I’m more confident today than I was 24 hours ago that if a small asteroid was on a collision course with Earth, we could do something about it.”
The good news, then, is that we can now apparently guard against the menace that killed off the dinosaurs 66mn years ago. The not-so-good news is that bigger existential risks to humanity lie closer to home.
Asteroids are rocky objects, smaller than planets, that orbit the Sun (comets, in contrast, are made of ice, rock and gas). Most of the million-plus known specimens lie in the main asteroid belt between Mars and Jupiter. Of biggest concern are potentially hazardous ones, which are at least 140m across and have orbits that come within 7.5mn km of Earth — big and close enough to strike Terra Firma but small enough to evade early detection. That made Dimorphos the perfect target: about the right size (160m), and too distant to pose a risk.
One reason why the Double Asteroid Redirection Test, or Dart, mission captivated the public was its dazzling demonstration of technical chutzpah. While most space jaunts are geared towards avoiding calamitous encounters with asteroids, planets or space debris, engineering a deliberately destructive pas-de-deux between two speeding objects in the vast emptiness of space requires exquisite precision.
The 570kg Dart spacecraft, launched last year and guided by autonomous navigation, was travelling at about 6km/s, equivalent to 14,000mph, and designed to lock on to its target less than an hour before impact. The asteroid bullseye, meanwhile, flies through space at more than twice that speed. To see the boulder-strewn surface of Dimorphos in razor-sharp detail as Dart descended to its fate, was awe-inspiring.
More profoundly, though, the mission compels us to confront the agency we have over our destiny. Dart was humanity’s first attempt at intentionally moving a celestial object, affording us a smidgen of influence over cosmic forces hitherto outside our control. Its success does not mean we can now play billiards with space rocks but it does suggest a viable line of planetary defence should heavenly forces conspire against us, as they did against the dinosaurs.
Relief at being able to avert asteroid-induced catastrophe contrasts, though, with our relatively sanguine approach to other threats. A planetary disaster caused by an asteroid impact might happen once in a million years, suggests Lord Rees, Britain’s Astronomer Royal, co-founder of the Centre for the Study of Existential Risk at Cambridge university and author of If Science is to Save Us. But, “there are other substantial threats that could happen this century”.
While he regards asteroid deflection technology as prudent, Rees worries more about the misuse of biotechnology (particularly experiments that create toxic viruses), artificial intelligence, pandemics and, of late, nuclear aggression. His worst nightmare, he confesses, is a lone fanatic who slips through the governance net: “Technology gives even small groups of people the power to cause a global catastrophe, such as the release of a virus, cyber attacks on power grids or a breakdown in AI. Village idiots now have global range.”
When HG Wells summed up the risks to civilisation, he, too, toyed with the prospect of “some great unexpected mass” rushing “upon us out of space”. But also that “some pestilence may presently appear . . . there may come some drug or a wrecking madness into the minds of men”. Our ability to calculate our way out of an asteroid strike will count for little if we cannot restrain our own wrecking madnesses first.
Humanity’s most distant spacecraft is sending back weird signals from beyond our solar system
On Sept. 5, 1977, NASA launched a space probe named Voyager 1 into the cosmos. Nearly 45 years later, much to the delighted astonishment of astronomers throughout the world, it is still humming along as it travels far past Pluto.
In fact, Voyager 1 has traveled so far that it has left the bounds of our solar system — and now it is giving off strange readings that scientists are struggling to understand.
The mystery likely has something to do with the fact that Voyager 1 is the farthest artificial object in space. At a distance of 14.5 billion miles away from Earth, Voyager 1 passed through the heliopause in 2012. The heliopause is the barrier separating the Sun’s solar winds from the interstellar medium, or all of the matter and radiation that exist in the space in-between various solar systems in the galaxy. This means that Voyager 1 is literally in the interstellar void of the Milky Way.
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Perhaps that has something to do with why the Jimmy Carter-era machine is sending back signals that can best be described as strange.
“The interstellar explorer is operating normally, receiving and executing commands from Earth, along with gathering and returning science data,” NASA explained on its website. “But readouts from the probe’s attitude articulation and control system (AACS) don’t reflect what’s actually happening onboard.”
“We’re also in interstellar space – a high-radiation environment that no spacecraft have flown in before.”
More specifically, NASA explained, the AACS keeps the spacecraft’s antenna pointed at Earth so that it transmits data back to our planet. On the surface, the AACS appears to keep working, but all of the telemetry data that it has sent back is invalid, such as by appearing to be randomly generated or physically impossible. This raises questions.
“A mystery like this is sort of par for the course at this stage of the Voyager mission,” Suzanne Dodd, project manager for Voyager 1 and 2 at NASA’s Jet Propulsion Laboratory in Southern California, said in a statement. “The spacecraft are both almost 45 years old, which is far beyond what the mission planners anticipated.”
Dodd added, “We’re also in interstellar space – a high-radiation environment that no spacecraft have flown in before. So there are some big challenges for the engineering team. But I think if there’s a way to solve this issue with the AACS, our team will find it.”
RELATED: The Voyager 1 probe is now so far away that it can hear the background “hum” of interstellar space
This will not be a quick fix. A signal from Earth currently takes 20 hours and 33 minutes to reach Voyager 1, and vice-versa. Both Voyager 1 and its twin Voyager 2 are suffering from a dwindling power supply, forcing the engineers to turn off parts to save as much as they can. Some hope Voyager 1 will be able to continue to transmit data for as far into the future as 2025, after which point its radioisotope thermoelectric generators (RTGs) will no longer be able to summon enough energy to keep its equipment operative.
Even if Voyager 1 does prove to be on its last legs sooner than expected, it has still had a historic journey. As it flew by the gas giants of Jupiter and Saturn, as well as Saturn’s largest moon Titan, it obtained detailed images and unprecedented quantities of data. The Voyager probe famously contains a so-called “Golden Record” (actually two phonograph records) that preserve Earth’s culture to any extraterrestrial beings that may stumble upon and comprehend it. The gold-plated disks include everything from nature sounds to music by Wolfgang Amadeus Mozart and Chuck Berry.
Indeed, the Voyage 1 probe is now so deep into space that astronomers can literally hear the “hum” that our solar system produces as the spacecraft travels outside of it.
“It’s very faint and monotone, because it is in a narrow frequency bandwidth,” Stella Koch Ocker, a doctoral student in the Department of Astronomy and Cornell Center for Astrophysics and Planetary Science, told Salon at the time about the study of which she was lead author. “We’re detecting the faint, persistent hum of interstellar gas.”
A senior author — James Cordes, an astronomy professor at Cornell University — told Salon that “the interstellar medium is like a quiet or gentle rain. In the case of a solar outburst, it’s like detecting a lightning burst in a thunderstorm and then it’s back to a gentle rain.”
Read more Salon articles on space exploration:
Gorgeous HD Footage Shows Humanity’s Final View of The James Webb Space Telescope
We can all breathe a bit easier now. In spite of a launch bedeviled by problem after problem, NASA’s James Webb Space Telescope is finally in space, making its way to its new home.
And if you needed a little reassurance that this is the case (which is totally understandable), the European Space Agency has released footage from the Ariane 5 rocket, which filmed the telescope in glorious HD as it zoomed away.
In the three-minute real-time video, you can watch as Webb separates from the rocket, moving away, the solar array deploying after 69 seconds.
It’s headed for a location some 1.5 million kilometers (just under 1 million miles) from Earth, in a region called a Lagrange point.
Here, the combined gravitational forces of two larger bodies (in this case Earth and the Sun) create a small area of gravitational stability. Webb will sit in the second Lagrange point – there are five in total – on the far side of Earth from the Sun, also known as L2.
Not only will Webb be able to protect itself from the heat of the Sun, Earth, and Moon using its state-of-the-art sunshield, but it will also require the least amount of fuel, allowing its mission a much longer timeframe than other locations might.
That heat protection is crucial, by the way: The cryogenic temperatures at that distance will minimize the interference from heat sources that might mess with Webb’s infrared measurements of the early Universe.
Because it’s so much farther from Earth than Hubble, the Webb space telescope will need to operate with minimal human involvement. Engineers on the ground can communicate with the spacecraft, but we won’t be able to service it at all. That means that we need to be able to fix any issues that might arise remotely, so it was worth the extra months making sure everything was in perfect condition before launch.
Ariane 5’s parting footage will be the last time we clap eyes on Webb for some time, if we ever do again. It’s possible that another spacecraft will be able to snap a passing glimpse or two, but you shouldn’t bank on it. Webb isn’t equipped with any self-monitoring cameras; it would have been quite complicated to add them, so we can’t expect any fetching selfies as we see with the Mars rovers, for instance.
That’s OK. Webb’s got much bigger fish to fry when it reaches L2. It will arrive approximately a month after launch, so in a couple more weeks at the time of writing. Then it will need to be extensively tested and calibrated to make sure it’s operating properly. Only then – approximately six months after launch – will the telescope’s science operations commence.
We might expect to see “first light” images from the testing and calibration phase a little earlier than that. Meanwhile, we’ll be sitting here hoping that Webb’s journey goes smoothly.
Bon voyage, you glorious space telescope. Call home soon.