Breakthrough narrows intelligent life search in Milky Way

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Breakthrough narrows intelligent life search in Milky Way

 

An analytical breakthrough that could significantly improve our chances of finding extra-terrestrial life in our galaxy has been discovered by a team at

 

The University of Manchester.

 

In new research published today in Monthly Notices of the Royal Astronomical Society, the researchers demonstrate a reanalysis of existing data that

 

represents a new milestone in the Search for Extra-terrestrial Intelligence (SETI).

 

The collaborative research team has dramatically expanded the search for extra-terrestrial life from 1,400 stars to 280,000—increasing the number of

 

stars analysed by a factor of more than 200.

 

The result suggests that less than 0.04% of stellar systems have the potential of hosting advanced civilisations with the equivalent or slightly more

 

advanced radio technology than 21st century humans. As well as improving the limits for nearby stars, the team for the first time actually placed limits

 

on more distant stars with the caveat that any potential lifeforms inhabiting the outer limits of the galaxy would need even more powerful transmitters

 

in order to be detectable.

 

The analysis, say researchers, can only locate intelligent and technically advanced civilisations that use radio waves as a form of communication—they

 

could not, for example, detect "simple" life or non-technical civilisations.

 

 

The team is made up of Masters student Bart Wlodarczyk-Sroka and his advisor Professor Michael Garrett at the University of Manchester in the UK,

 

and Dr. Andrew Siemion, director of the Breakthrough Listen Initiative, have placed the best limits ever on the prevalence of artificial radio transmitters,

 

dubbed techno-signatures, in the Milky Way.

 

Combing through the catalogue produced by the European Space Agency's (ESA) Gaia spacecraft, which measured the distances to over a billion stars,

 

the researchers recalculated limits on the prevalence of transmitters around additional stars within the radio telescope's fields of view. By selecting

 

stars out to much larger distances (up to about 33,000 light years) than the original sample of nearby stars, they were able to expand the number of

 

stars studied from 1,327 to 288,315.

 

Team leader Mike Garrett had always been troubled that SETI searches didn't usually take into account the many other cosmic objects that fall within

 

the range of sky a telescope is sensitive to, in addition to the main target. According to Garrett, Gaia has changed all that: "Knowing the locations and

 

distances to these additional sources," he says, "greatly improves our ability to constrain the prevalence of extra-terrestrial intelligence in our own

 

galaxy and beyond. We expect future SETI surveys to also make good use of this approach."

 

"Our results help to put meaningful limits on the prevalence of transmitters comparable to what we ourselves can build using twenty first century

 

technology," remarked Wlodarczyk-Sroka.

 

"We now know that fewer than one in 1600 stars closer than about 330 light years host transmitters just a few times more powerful than the strongest

 

radar we have here on Earth. Inhabited worlds with much more powerful transmitters than we can currently produce must be rarer still."

 

The sheer number of stars studied enabled Wlodarczyk-Sroka to place some of the most stringent limits to date on the prevalence of powerful radio

 

transmitters in this region of our galaxy. In addition, for the first time, the team have been able to do this as a function of stellar type—the extended

 

sample includes not only a wide range of main-sequence stars, but also numerous giant stars and white dwarfs.

 

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