You can knock a good telescope out, but you can’t keep it down. Using data from the now-destroyed Arecibo radio telescope, scientists from the Search for Extraterrestrial Intelligence (SETI) Institute have unlocked the secrets of signals from “cosmic lighthouses” powered by dead stars.

In particular, the team led by Sofia Sheikh from the SETI Institute was interested in how the signals from pulsars distort as they travel through space. Pulsars are dense stellar remnants called neutron stars that blast out beams of radiation that sweep across the cosmos as they spin. When pulsars were first discovered in 1967 by Jocelyn Bell Burnell, some proposed the frequent and highly regular periodic pulsing of these remnants to be signals from intelligent life everywhere in the cosmos. To study how these stars’ signals are distorted in space, the team turned to archival data from Arecibo, a 1,000-foot (305-meter) wide suspended radio telescope that collapsed on Dec. 1, 2020, after the cables supporting it snapped.

The researchers investigated 23 pulsars, including 6 which had not been studied before. This data revealed patterns in pulsar signals showing how they were impacted by the passage through gas and dust that exists between stars, the so-called “interstellar medium.” When the cores of massive stars rapidly collapse to create neutron stars, they can create pulsars capable of spinning as fast as 700 times every second. The radio wave distortions the team was interested in are known as diffractive interstellar scintillation (DISS). DISS is somewhat analogous to the patterns of rippling shadows seen at the bottom of a pool as light passes through the water above. Instead of ripples in water, DISS is caused by charged particles in the interstellar medium that create distortions in radio wave signals traveling from pulsars to radio telescopes on Earth.

The team’s investigation revealed that the bandwidths of pulsar signals were wider than current models of the universe suggest should be the case. This further implied that current models of the interstellar medium may need to be revised. The researchers found that when galactic structures such as the spiral arms of the Milky Way were accounted for, the DISS data was better explained. This suggests that challenges in modeling the structure of our galaxy should be faced in order to continually update galactic structure models.

Understanding how signals from pulsars work is important to scientists because, when considered in large arrays, the ultraprecise periodic signals from pulsars can be used as a timing mechanism.

The team’s research was published on Nov. 26 in The Astrophysical Journal.

Source: Space.com