If extraterrestrial intelligence exists somewhere in our galaxy, a new study from the Massachusetts Institute of Technology (MIT), in the United States, proposes that laser technology on Earth could, in principle, be fashioned into something of a planetary porch light — a beacon strong enough to attract attention from as far as 20,000 light years away.
The research, which author James Clark calls a “feasibility study,” appears today in The Astrophysical Journal. The findings suggest that if a high-powered one- to two-megawatt laser were focused through a massive 30- to 45-metre (100- to 150-foot) telescope and aimed out into space, the combination would produce a beam of infrared radiation strong enough to stand out from the Sun’s energy.
Such a signal could be detectable by alien astronomers performing a cursory survey of our section of the Milky Way — especially if those astronomers live in nearby systems, such as around Proxima Centauri, the nearest star to Earth, or TRAPPIST-1, a star about 40 light years away that hosts seven exoplanets, three of which are potentially habitable. If the signal is spotted from either of these nearby systems, the study finds, the same megawatt laser could be used to send a brief message in the form of pulses similar to Morse code.
“If we were to successfully close a handshake and start to communicate, we could flash a message, at a data rate of about a few hundred bits per second, which would get there in just a few years,” says Clark, a graduate student in MIT’s Department of Aeronautics and Astronautics.
The notion of such an alien-attracting beacon may seem far-fetched, but Clark says the feat can be realised with a combination of technologies that exist now and that could be developed in the near term.
“This would be a challenging project but not an impossible one,” says Clark. “The kinds of lasers and telescopes that are being built today can produce a detectable signal, so that an astronomer could take one look at our star and immediately see something unusual about its spectrum. I don’t know if intelligent creatures around the Sun would be their first guess, but it would certainly attract further attention.”
Clark started looking into the possibility of a planetary beacon as part of a final project for 16.343 (Spacecraft, and Aircraft Sensors and Instrumentation), a course taught by Clark’s advisor, Associate Professor Kerri Cahoy.
“I wanted to see if I could take the kinds of telescopes and lasers that we’re building today, and make a detectable beacon out of them,” Clark says.
He started with a simple conceptual design involving a large infrared laser and a telescope through which to further focus the laser’s intensity. His aim was to produce an infrared signal that was at least 10 times greater than the Sun’s natural variation of infrared emissions. Such an intense signal, he reasoned, would be enough to stand out against the Sun’s own infrared signal, in any “cursory survey by an extraterrestrial intelligence.”
He analysed combinations of lasers and telescopes of various wattage and size, and found that a two-megawatt laser, pointed through a 30-metre telescope, could produce a signal strong enough to be easily detectable by astronomers in Proxima Centauri b, a planet that orbits our closest star, four light-years away. Similarly, a one-megawatt laser, directed through a 45-metre telescope, would generate a clear signal in any survey conducted by astronomers within the TRAPPIST-1 planetary system, about 40 light-years away. Either setup, he estimated, could produce a generally detectable signal from up to 20,000 light-years away.
Both scenarios would require laser and telescope technology that has either already been developed, or is within practical reach. For instance, Clark calculated that the required laser power of one to two megawatts is equivalent to that of the U.S. Air Force’s Airborne Laser, a now-defunct megawatt laser that was meant to fly aboard a military jet for the purpose of shooting ballistic missiles out of the sky. He also found that while a 30-metre telescope considerably dwarfs any existing observatory on Earth today, there are plans to build such massive telescopes in the near future, including the 24-metre (79-foot) Giant Magellan Telescope and the 39-metre (128-foot) European Extremely Large Telescope, both of which are currently under construction in Chile.
Clark envisions that, like these massive observatories, a laser beacon should be built atop a mountain, to minimise the amount of atmosphere the laser would have to penetrate before beaming out into space.
He acknowledges that a megawatt laser would come with some safety issues. Such a beam would produce a flux density of about 800 watts of power per square meter, which is approaching that of the Sun, which generates about 1,300 watts per square metre. While the beam wouldn’t be visible, it could still damage people’s vision if they were to look directly at it. The beam could also potentially scramble any cameras aboard spacecraft that happen to pass through it.
“If you wanted to build this thing on the far side of the Moon where no one’s living or orbiting much, then that could be a safer place for it,” says Clark. “In general, this was a feasibility study. Whether or not this is a good idea, that’s a discussion for future work.”
Having established that a planetary beacon is technically feasible, Clark then flipped the problem and looked at whether today’s imaging techniques would be able to detect such an infrared beacon if it were produced by astronomers elsewhere in the galaxy. He found that, while a telescope one metre (three foot) or larger would be capable of spotting such a beacon, it would have to point in the signal’s exact direction to see it.
“It is vanishingly unlikely that a telescope survey would actually observe an extraterrestrial laser, unless we restrict our survey to the very nearest stars,” says Clark.
He hopes the study will encourage the development of infrared imaging techniques, not only to spot any laser beacons that might be produced by alien astronomers, but also to identify gases in a distant planet’s atmosphere that might be indications of life.
“With current survey methods and instruments, it is unlikely that we would actually be lucky enough to image a beacon flash, assuming that extraterrestrials exist and are making them,” says Clark. “However, as the infrared spectra of exoplanets are studied for traces of gases that indicate the viability of life, and as full-sky surveys attain greater coverage and become more rapid, we can be more certain that, if E.T. is phoning, we will detect it.”
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