Rethinking infrared emissions
Earlier models suggested that much of the infrared radiation detected near active galactic nuclei came from high-speed outflows of hot material. Webb’s observations tell a different story.
The data show that the vast majority of infrared light in Circinus comes from dense dust very close to the black hole itself, within the thick torus of material feeding it. Researchers found that approximately 87% of the infrared emission originates near the accretion disk, while less than 1% comes from dusty outflows. The remaining emission comes from dust farther away that could not previously be distinguished.
Explaining the challenge researchers faced, lead author Enrique Lopez-Rodriguez said in a NASA statement:
“Since the ‘90s, it has not been possible to explain excess infrared emissions that come from hot dust at the cores of active galaxies, meaning the models only take into account either the torus or the outflows, but cannot explain that excess.”
Webb’s interferometry breakthrough
The Aperture Masking Interferometer played a crucial role by filtering out surrounding starlight and reconstructing fine details from interference patterns. This marks the first time such a technique has been used from space to study an object beyond the Milky Way.
Co-author Joel Sanchez-Bermudez of the National Autonomous University of Mexico explained the impact of the method:
