Scientists have long theorized that nearly every large galaxy houses a supermassive black hole at its core. However, direct observation is impractical due to their immense numbers, potentially reaching trillions across the universe. To address this challenge, researchers extrapolate from smaller samples. Accurately determining the proportion of obscured black holes in these samples is essential for estimating the total population of these celestial objects.

Published in the *Astrophysical Journal*, the study revealed that approximately 35% of supermassive black holes are heavily obscured, surrounded by clouds dense enough to block even low-energy X-ray light. This figure is significantly higher than earlier estimates, which suggested fewer than 15% of these black holes were so concealed. However, theoretical models of galaxy formation predict that roughly half of all supermassive black holes should be hidden. If future research continues to find fewer obscured black holes than expected, scientists may need to reconsider their understanding of these enigmatic entities and their impact on galactic development.

Shedding Light on Hidden Black Holes

Most telescopes struggle to identify edge-on black holes, but NASA's Infrared Astronomical Satellite (IRAS), which operated for 10 months in 1983, was a notable exception. Managed by NASA's Jet Propulsion Laboratory (JPL), IRAS detected infrared light emitted by the obscuring torus, enabling scientists to spot hidden black holes as effectively as visible ones. The satellite identified hundreds of potential targets, but distinguishing between obscured black holes and star-forming galaxies with similar infrared signatures required additional analysis using ground-based telescopes.

To confirm the presence of heavily obscured black holes, researchers turned to NASA's NuSTAR (Nuclear Spectroscopic Telescope Array). This X-ray observatory detects high-energy X-rays that can penetrate the surrounding clouds, providing definitive evidence of obscured black holes. Since these observations require significant time, the team used IRAS data to narrow their focus to the most promising targets.

"It amazes me how useful IRAS and NuSTAR were for this project, especially despite IRAS being operational over 40 years ago," said Peter Boorman, lead author of the study and an astrophysicist at Caltech. "I think it shows the legacy value of telescope archives and the benefit of using multiple instruments and wavelengths of light together."

Uncovering Cosmic Insights

Black holes also significantly influence their host galaxies by regulating star formation. When black holes consume material too quickly, they expel excess gas back into the galaxy, dispersing star-forming clouds and slowing stellar birth rates. "If we didn't have black holes, galaxies would be much larger," said Poshak Gandhi, a professor of astrophysics at the University of Southampton and coauthor of the study. "So if we didn't have a supermassive black hole in our Milky Way galaxy, there might be many more stars in the sky. That's just one example of how black holes can influence a galaxy's evolution."

This research represents a significant step toward understanding the hidden universe of supermassive black holes and their role in shaping galaxies. By combining data from multiple telescopes and wavelengths, the study offers a clearer picture of these enigmatic cosmic giants.

Research Report:The NuSTAR Local AGN NH Distribution Survey (NuLANDS). I. Toward a Truly Representative Column Density Distribution in the Local Universe

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