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Peering into a galaxy's dusty core to study an active supermassive black hole by Claire Blome and Christine Pulliam for Hubble News Baltimore MD (SPX) Mar 18, 2021
Researchers using NASA's upcoming James Webb Space Telescope will map and model the core of nearby galaxy Centaurus A. Centaurus A is a giant of a galaxy, but its appearances in telescope observations can be deceiving. Dark dust lanes and young blue star clusters, which crisscross its central region, are apparent in ultraviolet, visible, and near-infrared light, painting a fairly subdued landscape. But by switching to X-ray and radio light views, a far more raucous scene begins to unfold: From the core of the misshapen elliptical galaxy, spectacular jets of material have erupted from its active supermassive black hole - known as an active galactic nucleus - sending material into space well beyond the galaxy's limits. What, precisely, is happening at its core to cause all this activity? Upcoming observations led by Nora Lutzgendorf and Macarena Garcia Marin of the European Space Agency using NASA's James Webb Space Telescope will allow researchers to peer through its dusty core in high resolution for the first time to begin to answer these questions. "There's so much going on in Centaurus A," explains Lutzgendorf. "The galaxy's gas, disk, and stars all move under the influence of its central supermassive black hole. Since the galaxy is so close to us, we'll be able to use Webb to create two-dimensional maps to see how the gas and stars move in its central region, how they are influenced by the jets from its active galactic nucleus, and ultimately better characterize the mass of its black hole."
A Quick Look Back With more observations in the early 2000s, researchers estimated that about 10 million years ago, its active galactic nucleus shot out twin jets in opposite directions. When examined across the electromagnetic spectrum, from X-ray to radio light, it's clear there is far more to this story that we still have to learn. "Multi-wavelength studies of any galaxy are like the layers of an onion. Each wavelength shows you something different," said Marin. "With Webb's near- and mid-infrared instruments, we'll see far colder gas and dust than in previous observations, and learn much more about the environment at the center of the galaxy."
Visualizing Webb's Data In particular, Webb's Near Infrared Spectrograph (NIRSpec and Mid-Infrared Instrument (MIRI) will provide the research team with a combination of data: an image plus a spectrum from within each pixel of that image. This will allow the researchers to build intricate 2D maps from the spectra that will help them identify what's happening behind the veil of dust at the center - and analyze it from many angles in depth. Compare this style of modeling to the analysis of a garden. In the same way botanists classify plants based on specific sets of features, these researchers will classify spectra from Webb's MIRI to construct "gardens" or models. "If you take a snapshot of a garden from a great distance away," Marin explained, "You will see something green, but with Webb, we will be able to see individual leaves and flowers, their stems, and maybe the soil underneath." As the research team digs into the spectra, they'll build maps from individual parts of the garden, comparing one spectrum to another nearby spectrum. This is analogous to determining which parts contain which plant species based on comparisons of "stems," "leaves," and "flowers" as they go. "When it comes to spectral analysis, we conduct many comparisons," Marin continued. "If I compare two spectra in this region, maybe I will find that what was observed contains a prominent population of young stars. Or confirm which areas are both dusty and heated. Or maybe we will identify emission coming from the active galactic nucleus." In other words, the "ecosystem" of spectra has many levels, which will allow the team to better define precisely what is present and where it is - which is made possible by Webb's specialized infrared instruments. And, since these studies will build on many that came before, the researchers will be able to confirm, refine, or break new ground by identifying new features.
Weighing the Black Hole in Centaurus A Since researchers understand how the gravity of a black hole governs the rotation of nearby gas, they can use the Webb data to weigh the black hole in Centaurus A. With a more complete set of infrared data, they will also determine if different parts of the gas are all behaving as anticipated. "I'm looking forward to fully filling out our data," Lutzgendorf said. "I hope to see how the ionized gas behaves and twirls, and where we see the jets." The researchers are also hoping to break new ground. "It's possible we'll find things we haven't considered yet," Lutzgendorf explains. "In some aspects, we'll be covering completely new territory with Webb." Marin wholeheartedly agrees, and adds that building on a wealth of existing data is invaluable. "The most exciting aspects about these observations is the potential for new discoveries," she said. "I think we might find something that makes us look back to other data and reinterpret what was seen earlier." These studies of Centaurus A will be conducted as part of Gillian Wright and Pierre Ferruit's joint MIRI and NIRSpec Guaranteed Time Observations programs. All of Webb's data will ultimately be stored in the publicly accessible Barbara A. Mikulski Archive for Space Telescopes (MAST) at the Space Telescope Science Institute in Baltimore.
Astronomers detect a black hole on the move Washington DC (SPX) Mar 15, 2021 Scientists have long theorized that supermassive black holes can wander through space--but catching them in the act has proven difficult. Now, researchers at the Center for Astrophysics | Harvard and Smithsonian have identified the clearest case to date of a supermassive black hole in motion. Their results are published in the Astrophysical Journal. "We don't expect the majority of supermassive black holes to be moving; they're usually content to just sit around," says Dominic Pesce, an astr ... read more
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