Over 2,500 years ago, two small stars collided. The collision produced an outburst called a red nova, which then slowly cooled, producing molecular gas and dust. By the time the light from the nova reached Earth in 1670, astronomers were already keenly observing heavens with telescopes. They noted the event and kept records as the outburst faded over nearly two years. Recently, astronomers took a closer look at the remnant and saw a something never seen in space before — an object producing radioactive elements.Decades ago, astronomers found a unique radioactive signature when observing the sky with a gamma-ray telescope. They found the signature of beta decays (a type of radioactive decay that emits an electron) of an isotope of aluminum,Al, sprinkled across the sky. Ever since, astronomers have been searching for the source of the aluminum, but due to the resolution of available instruments, they were unable to identify it. Now, with the improved resolution of the Atacama Large Millimeter/submillimeter Array and the Northern Extended Millimeter Array, a team of researchers has pinpointed one source producing the aluminum: CK Vulpeculae, the merger remnant of the nova spotted in 1670.“Mergers of normal stars have never been considered before as sources of aluminum-26,” said Tomek Kaminski, lead author on the paper, published July 30 in Nature Astronomy, and astronomer at the Harvard-Smithsonian Center for Astrophysics. “The usual suspects were massive Wolf-Rayet stars asymptotic giant branch stars , and classical novae .”The nuclear reactions that create this isotope of aluminum are well known. However, where it is produced, and how it is released into interstellar space, are more open questions. Astronomers know aluminum is not produced in Sun-sized stars, except for at the end of their lifetime. When a star runs out of hydrogen at its core, it starts burning the remaining hydrogen in an outer shell. At this stage, the star enters the red giant branch and begins to produce a small amount of the aluminum isotope. Given the amount of the isotope found in CK Vulpeculae, the researchers believe one of the stars was in this phase of its life when the two collided.