NASA finally reached the end of the observable universe. Astronomers have long grappled with understanding how the earliest black holes formed in the infancy of the universe. Prevailing theories held that these cosmic behemoths emerged either from collapsing massive gas clouds or through the mergers of smaller black holes. But confirming their existence—and pinpointing their origins—proved elusive due to the vast distances and limited observational tools.
NASA made a new discovery at the edge of the universe: it’s older than the Milky Way
Recent leaps in observational technology, especially with the James Webb Space Telescope, have shattered previous limits. Scientists can now detect galaxies and black holes that existed mere hundreds of millions of years after the Big Bang. These findings offer unprecedented insights into how the universe’s earliest structures took shape and challenge long-standing assumptions.
Among the most remarkable discoveries is a galaxy named CAPERS-LRD-z9, roughly 13.3 billion light-years away. At its core lies a supermassive black hole weighing about 300 million suns—an enormous mass for an object so close to the dawn of time. This challenges directly the current models of black hole growth.
NASA captured the “first light” in the cosmos: Is there anything beyond?
Light captured by NASA’s telescopes has been traveling for 13.3 billion years, carrying the signature of a black hole in a faint galaxy named CAPERS-LRD-z9. This system existed just 500 million years after the Big Bang, when the cosmos was only about 3% of its current age.
It belongs to a formative era, when gas, stars, and black holes were coalescing under conditions unlike anything in today’s universe. Detecting it required the precision of modern spectroscopy and years of deep-sky surveys. Its presence offers a glimpse at how quickly some black holes reached enormous masses in the early universe.
The discovery, published on August 6 in the Astrophysical Journal, marks one of the farthest confirmed black holes found through direct spectroscopic evidence. NASA used light-splitting techniques to reveal the motion of gas around the object — stretched toward red wavelengths on the far side and compressed toward blue on the near side — a pattern that few cosmic phenomena besides black holes can produce. This signature, paired with the galaxy’s unusual color and brightness, pointed to a central black hole.
The telescope was looking back in time: It was only visible now
The data came from the NASA’s James Webb Space Telescope’s CANDELS-Area Prism Epoch of Reionization Survey (CAPERS), a program designed to chart the most distant galaxies known. As CAPERS identifies more systems like this, researchers expect to learn how common early massive black holes were, how they shaped their host galaxies, and how rapidly their environments evolved.
A separate study captured the first spectroscopic confirmation of a repeated partial tidal-disruption event — a star losing some of its outer layers each time it swings past its galaxy’s central black hole, then surviving to return. The repeat pattern suggests a steady two-year orbital cycle, providing a rare, clear example of a black hole feeding in small, periodic bursts.
Black holes are the cosmic destroyer that shaped the cosmos
Together, these findings stretch the timeline of black hole influence from the dawn of galaxies to the present day. CAPERS-LRD-z9 fixes the presence of a massive black hole at a time when the universe was still in its infancy. The tidal-disruption case shows how, billions of years later, black holes continue shaping their surroundings — whether by igniting the centers of compact young galaxies or slowly stripping stars on regular schedules. NASA continues committed not only to look for life in other exoplanets, but also searching for leads about the beginning of everything.