A new study by Penn State and the SETI Institute explored alien signal detection in the TRAPPIST-1 system using innovative techniques focused on planetary alignments.
Astronomers have developed a new technique to search for radio signals from planets beyond our solar system, particularly those aligned with both each other and Earth. These signals would be similar to those used for communication with rovers on Mars. Penn State astronomers, in collaboration with scientists at the SETI Institute, spent 28 hours using the Allen Telescope Array (ATA) to scan the TRAPPIST-1 star system for signs of alien technology. This effort represents the longest focused search for radio signals from TRAPPIST-1 to date.
Although no evidence of extraterrestrial technology was found, the project introduced a new method for future searches. The research has been accepted for publication in the Astronomical Journal.
Enhancing Detection Technology for Extraterrestrial Signals
“This research shows that we are getting closer to technology and methods that could detect radio signals similar to the ones we send into space,” said Nick Tusay, a graduate student research fellow at Penn State and first author of the paper. “Most searches assume a powerful signal, like a beacon intended to reach distant planets, because our receivers have a sensitivity limit to a minimum transmitter power beyond anything we unintentionally send out. But, with better equipment, like the upcoming Square Kilometer Array, we might soon be able to detect signals from an alien civilization communicating with its spacecraft.”
The project focused on a phenomenon called planet-planet occultations (PPOs). PPOs happen when one planet moves in front of another from Earth’s perspective. If intelligent life exists in that star system, radio signals sent between planets could leak and be detected from Earth.
Advancements in Signal Analysis at ATA
Using the upgraded ATA — a series of radio antennae dedicated to the search for extraterrestrial technology located at the Hat Creek Observatory in the Cascade Mountains about 300 miles north of San Francisco — the team scanned a wide range of frequencies, looking for narrowband signals, which are considered possible signs of alien technology. The team filtered millions of potential signals, narrowing down to about 11,000 candidates for detailed analysis. The team detected 2,264 of these signals during predicted PPO windows. However, none of the signals were of non-human origin.
The ATA’s new capabilities, which include advanced software to filter signals, helped the team separate possible alien signals from Earth-based ones. The researchers said they believe that refining these methods and focusing on events like PPOs could help increase the chances of detecting alien signals in the future.
SETI Research and Student Involvement
“This project included work by undergraduate students in the 2023 SETI Institute Research Experience for Undergraduates program,” said Sofia Sheikh, a SETI researcher at the SETI Institute who earned her doctoral degree at Penn State. “The students looked for signals from human-made orbiters around Mars to check if the system could detect signals correctly. It was an exciting way to involve students in cutting-edge SETI research.”
The TRAPPIST-1 system is a small, cool star about 41 light years from Earth. It has seven rocky planets, some of which are in the habitable zone, where conditions might allow liquid water to exist — an essential ingredient for life as we know it. This makes TRAPPIST-1 a prime target searching for life beyond Earth.
Future Directions in Astronomical Research
“The TRAPPIST-1 system is relatively close to Earth, and we have detailed information about the orbit of its planets, making it an excellent natural laboratory to test these techniques,” Tusay said. “The methods and algorithms that we developed for this project can eventually be applied to other star systems and increase our chances of finding regular communications among planets beyond our solar system, if they exist.”
The team did not find any alien signals this time, but they will continue improving their search techniques and exploring other star systems. Future searches with bigger and more powerful telescopes could help scientists detect even fainter signals and expand our understanding of the universe, the team said.
For more on this study, see How SETI’s Latest Technology Scoured TRAPPIST-1 for Otherworldly Communications.
Reference: “A Radio Technosignature Search of TRAPPIST-1 with the Allen Telescope Array” by Nick Tusay, Sofia Z. Sheikh, Evan L. Sneed, Wael Farah, Alexander W. Pollak, Luigi F. Cruz, Andrew Siemion, David R. DeBoer and Jason T. Wright, Accepted, The Astronomical Journal.
DOI: 10.48550/arXiv.2409.08313
In addition to Tusay and Sheikh, the research team includes Jason T. Wright at Penn State; Evan L. Sneed at the University of California, Riverside; Wael Farah, Andrew Siemion and David R. DeBoer at the University of California, Berkeley; and Alexander W. Pollak and Luigi F. Cruz at the SETI Institute. This research was primarily funded through grants from the U.S. National Science Foundation with additional support from the Penn State Extraterrestrial Intelligence Center and the Penn State Center for Exoplanets and Habitable Worlds, which are supported by the Penn State and the Penn State Eberly College of Science.