For the first time, astronomers have glimpsed the dawn of the universe 13.6 billion years ago when the earliest stars were just beginning to glow after the Big Bang. And if that’s not enough, they may have detected mysterious dark matter at work, too.

The glimpse consisted of a faint radio signal from deep space, picked up by an antenna that is slightly bigger than a refrigerator and costs less than $5 million but in certain ways can go back much farther in time and distance than the celebrated, multibillion-dollar Hubble Space Telescope.

Judd Bowman of Arizona State University, lead author of a study in journal Nature, said the signal came from the very first objects in the universe as it was emerging out of darkness 180 million years after the Big Bang.

Seeing the universe lighting up, even if only via a faint signal, is even more important than the Big Bang because “we are made of star stuff and so we are glimpsing at our origin,” said astronomer Richard Ellis, who was not involved in the project.

The signal showed unexpectedly cold temperatures and an unusually pronounced wave. The best explanation is that elusive dark matter may have been at work, astronomers said. If verified, that would be the first confirmation of its kind of dark matter, which is a substantial part of the universe that scientists have been searching for over decades.

“If confirmed, this discovery deserves two Nobel Prizes” for both capturing the signal of the first stars and potential dark matter confirmation, said Harvard astronomer Avi Loeb, who wasn’t part of the research team. Cautioning that “extraordinary claims require extraordinary evidence,” he said independent tests are needed to verify the findings.

Bowman agreed that independent tests are needed even though his team spent two years double- and triple-checking their work. “It’s a time of the universe we really don’t know anything about,” Bowman said.

He said the discovery is “like the first sentence” in an early chapter of the history of the cosmos. But now that astronomers know where and how to look, others will confirm this and learn more, he said.

This is nothing that astronomers could actually see. It’s all based on changes in the wavelengths produced by radio signals.

The early universe was black and cold, filled with just hydrogen and helium. Once stars formed, they emitted ultraviolet light, which changes the energy signature of hydrogen atoms. Astronomers looked at a specific wavelength. If there were stars and ultraviolet light, they would see one signature. If there were no stars, they would see another. They saw a clear but faint signal showing there were stars, Bowman said.

Finding that trace signal wasn’t easy because the Milky Way galaxy alone booms with radio wave noise 10,000 times louder, said Peter Kurczynski, advanced program technology director for the National Science Foundation, which helped fund the research. “Finding the impact of the first stars in that cacophony would be like trying to hear the flap of a hummingbird’s wing from inside a hurricane,” he said.

When the signal was found and examined, it showed that the hydrogen between stars was “even colder than the coldest we thought possible,” said Rennan Barkana, a Tel Aviv University astrophysicist who wrote a companion study on the dark matter implications. The researchers expected temperatures to be 10 degrees above absolute zero, but they were 5 degrees above absolute zero (minus 451 degrees Fahrenheit). “The only thing we know from this signal is that something very weird is going on,” Barkana said.

What seems likely is dark matter — which scientists have never seen interacting with anything — may be cooling that hydrogen, he said. Dark matter makes up about 27 percent of the universe, but scientists little about it except that it’s not made of normal matter particles called baryons.

Scientists have known dark matter exists, indirectly, through measurements based on gravity. If this interpretation of the data is correct, it would be the first confirmation of dark matter outside of gravity calculations, Barkana said.

“If the result is correct it constitutes an indirect detection of dark matter and, moreover suggests something of fundamental importance (its interaction with baryons),” said Johns Hopkins University astrophysicist Marc Kamionkowski. “This therefore is about as important as you can get in cosmology.”