Australian National University researchers light up our pathway to another planetary system in major scientific breakthrough – ABC News

Posted: June 9, 2021 at 2:47 am

What lies beyond our solar system has long fascinated not just scientists but also writers and filmmakers, so murky are its depths.

And even the two probes that have made it beyond the heliosphereand into interstellar space Voyagers 1 and 2 did so only after decades of exploring our own planetarysystem.

Now, Canberra researchers say they have cracked the code to enable usto send a spacecrafteven further, and at a far greater speed, to another planetarysystem altogether.

The spacecraft is alsoso small and delicatethat scientistsplanto send more than one in the hope thatsome of them will make it to Alpha Centauri, without being destroyed by an errant piece of space dust along the way.

The achievement is "very exciting"because it could enable us to record information from those planetary bodieswithin our lifetime its predicted travel time is just 20 years.

Compare that to the roughly 44 years Voyager 2 spent nosing around Uranus and Neptune before continuing into the great beyond.

The study's lead author, Australian National University astrophysicist Chathura Bandutunga, said when they discovered the solution it was a kind of "eureka moment", when they worked out how many lasers, and in what formation, they would need to propel their spacecraft far enough and fast enough to reach its goal.

"We already have several crafts Voyager included [in interstellar space]but it will be many human lifetimes before they reach anywhere near another star," Dr Bandutunga said.

"For the Breakthrough Starshot probe to reach Alpha Centauri within one lifetime it will need to travel over 2000 times faster than our current interstellar probes."

Supplied: Breakthrough Initiatives

DrBandutunga said the whole project was "very ambitious", but one researchers were finally confident enough to share with their collaborators around the world.

"The challenge that we're really looking at is how do we use light to push the satellite along?" he said.

"And how do we get that light from a ray that's on the ground all the way to the satellite in orbit? How to do that on a grand scale that's really unheard of to date."

If their theory is correct, the lasers will be arranged in just the right combination and number to propel the sail to where it needs to go, and the next step is to test that theory within the laws of physics.

"The next step is to test the building blocks in a laboratory setting," he said.

Ideally, a spacecraft will reach Alpha Centauri,the closest star system and closest planetary system to Earth's, and record images and scientific measurements that will be broadcast back to Earth.

Scientistsestimate roughly 100 million individual lasers will be needed to generate the required optical power of about 100GW.

Fellow author Paul Sibley said the devil was in the detail when it came to unscrambling the lasers.

"We use a random digital signal to scramble the measurements from each laser and unscramble each one separately in digital signal processing,"he said.

This allows us to pick out only the measurements we need from a vast jumble of information. We can then break the problem into small arrays and link them together in sections."

While these measurements may seem confounding to the average eye, what is clear is that scientists have never got this close before.

"This project is really about making that travel from our star to another star possible within a human lifetime," Dr Bandutunga said.

University of Southern Queensland professor of astrophysics Jonti Horner described the development as a "brilliant"step forward in space exploration research.

"I think it's really fun," Dr Horner said.

"It puts an interesting spin on something people already do in astronomy.

"I think it's a beautiful illustration of how something that has been developed for one purpose can be repurposed for a totally different project.

"Instead of unscrambling the effect that the atmosphere has on light coming in, you're preemptively scrambling the light going out so that the atmosphere unscrambles it."

Dr Horner said the breakthrough was an exciting one because it was using existing technology to do something groundbreaking, where data from distant stars could be sent back within 25 years.

"It's a really fascinating example of where the investment of money and science leads to remarkable results,"he said.

"This idea that if we could speed the spacecraft up to a quarter of the speed of light, you could get it to the nearest star within 15 or 20 years.

"It's saying this is possible, likely with technology that's not much more further advanced than what we have now, so it's not science fiction, it's near-future technology."

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Australian National University researchers light up our pathway to another planetary system in major scientific breakthrough - ABC News

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