Title: XRISM Spectroscopy of the Fe Kα Emission Line in the Seyfert Active Galactic Nucleus NGC 4151 Reveals the Disk, Broad-line Region, and Torus
Authors: XRISM Collaboration
Status: Published in ApJL
Today we’re going to be taking a high-resolution look at X-rays from
close to a supermassive black hole! But before we get into the
astrophysics of today’s article, we first need to discuss the
instruments that were built to do this science. More than 50 years ago now, charge-coupled devices (CCDs)
began revolutionizing astronomy, and they continue to be one of the
most commonly used detectors on telescopes. CCDs rely on the photoelectric effect,
through which an incoming photon can liberate electrons in some
material (semiconductors in the case of CCDs). These electrons are
trapped by strong potential wells and electric charge can be applied to
move the charge along and read this signal (check out this Astrobite for more details). CCDs are particularly powerful in the X-ray
band, where the number of electrons trapped in each pixel scales
roughly with the photon energy. This means that you get energy
information (i.e., a spectrum) for free with CCDs! However, CCDs have limited spectral resolution, meaning they can’t determine this energy very precisely and therefore cannot resolve and unlock the power of narrow emission and absorption lines.
X-Ray Microcalorimetry and 20/20 Vision
There are other ways to get better spectral resolution in the X-ray, including using gratings that will disperse
your spectrum, as is commonly done with optical spectroscopy. However,
even these techniques can’t reach the high spectral resolution needed;
instead, new technology called a microcalorimeter
has been engineered to solve this long-standing issue. As the name
suggests, this instrument detects incoming photons by measuring tiny
(micro) changes to the temperature (calorimetry) of the detector. Figure
1 shows the basic set-up of a microcalorimeter and how the energy of
the photon is encoded in the strength of the resulting temperature
fluctuation. In order to detect tiny changes to the temperature,
microcalorimeters need to be extremely cold, 50 millikelvin to be
precise! This is a huge engineering feat, but one that has recently been
achieved by the X-ray Imaging and Spectroscopy Mission (XRISM)! XRISM is a JAXA/NASA
collaborative mission, and it has two instruments on board: a CCD
camera called Xtend and a microcalorimeter called Resolve. It was launched in September 2023, and its first science results are just starting to roll in!
Now, XRISM isn’t actually the first X-ray microcalorimeter to fly, but it’s the first to live through its commissioning phase! Although the X-ray microcalorimeter has been in the works since the 1990s, previous X-ray microcalorimeters have been cut from missions, lost to launch failures, and left unable to operate due to loss of coolant for the detector. In 2016, JAXA successfully launched and operated the first X-ray microcalorimeter on the Hitomi Satellite. However, unfortunately, shortly after taking a beautiful spectrum of the Perseus Cluster, one of the best-studied galaxy clusters in the local universe, communication was lost with the satellite and never recovered. XRISM’s Resolve instrument has been the most successful X-ray microcalorimeter so far, and it has allowed us to start looking at the universe with 20/20 X-ray vision!
Now, XRISM isn’t actually the first X-ray microcalorimeter to fly, but it’s the first to live through its commissioning phase! Although the X-ray microcalorimeter has been in the works since the 1990s, previous X-ray microcalorimeters have been cut from missions, lost to launch failures, and left unable to operate due to loss of coolant for the detector. In 2016, JAXA successfully launched and operated the first X-ray microcalorimeter on the Hitomi Satellite. However, unfortunately, shortly after taking a beautiful spectrum of the Perseus Cluster, one of the best-studied galaxy clusters in the local universe, communication was lost with the satellite and never recovered. XRISM’s Resolve instrument has been the most successful X-ray microcalorimeter so far, and it has allowed us to start looking at the universe with 20/20 X-ray vision!
Supermassive Science with XRISM
Today we’re going to put on our high-resolution X-ray spectroscopy glasses to look at one of the first XRISM targets: NGC 4151, one of the most well-known active galactic nuclei in the local universe. An active galactic nucleus consists of a supermassive black hole that is gobbling down gas from its surroundings through a process known as accretion.
While we’ve known about active galactic nuclei for more than 50 years
now, we still don’t really understand how they are fueled and what the
structure is around them. XRISM can unlock this information indirectly
by resolving some of the key X-ray emission and absorption lines. In
particular, the most prominent emission line in the X-ray spectrum of an
active galactic nucleus is a neutral iron Kα line at 6.4 kiloelectronvolts (keV),
which arises from material around the supermassive black hole being
illuminated by the light from the accretion process. This line holds the
keys to probing the structure of the surrounding gas, as its dynamics
can tell us about the structure of the accretion disk and trace gas in
the torus that is thought to connect the local host galaxy to the accretion flow.
Figure 3: Schematic highlighting where each of the iron Kα emission lines arise from. The magenta component corresponds to the broadest line, potentially from a warp in the disk. The dark blue component corresponds to the intermediate-width line and arises from the inner edge of the broad line region (BLR). The cyan component corresponds to the narrowest line and arises from the inner edge of the active galactic nucleus torus. Credit: XRISM Collaboration et al. 2024
What’s Next?
Original astrobite edited by Roel Lefever
Figure 2 shows the XRISM Resolve spectrum of NGC 4151 from two
separate observations. The spectrum shows a prominent 6.4 keV line that
is resolved, meaning that the measured width of the line is greater than
the instrument’s resolution limit. Additionally, the line cannot be fit
with a single emission line and instead requires multiple lines,
signaling multiple physical scales contributing to this emission line.
The right panels of this figure highlight that there are three distinct
components to this emission line with broad (magenta), intermediate
(dark blue), and narrow (cyan) widths. Since gas that is closer to the
black hole will be moving faster than more distant gas, the authors can
use these line widths to estimate where this gas is located. They find
that these three lines range from about 100 gravitational radii
(about 100 times the size of the black hole) to about 10,000
gravitational radii. Determining the multi-scale nature of this line has
been extraordinarily difficult to detect with other instruments due to
their limited energy resolution!
Together these three components to the iron Kα line provide a compelling picture for the nuclear structure, which is shown in Figure 3. There are some additional pieces of evidence from the data that support this model as well. For example, the broadest line (magenta) shows variability on timescales of less than a day. This timescale corresponds roughly to the distance light could travel before reaching the magenta part of this figure, supporting the idea that there is a broad component associated with the disk. In addition to the location of the emitting gas, the dynamics and density can be constrained using the energy and shape of the line, respectively. In this source, the line is at the rest-frame energy and the shape is relatively symmetric, which together suggest that the emission comes from relatively optically thin gas that has not been accelerated to high velocities. Together, these diagnostics give one of the most in-depth pictures of supermassive black hole environments to date and will be crucial for testing our models of black hole feeding!
Together these three components to the iron Kα line provide a compelling picture for the nuclear structure, which is shown in Figure 3. There are some additional pieces of evidence from the data that support this model as well. For example, the broadest line (magenta) shows variability on timescales of less than a day. This timescale corresponds roughly to the distance light could travel before reaching the magenta part of this figure, supporting the idea that there is a broad component associated with the disk. In addition to the location of the emitting gas, the dynamics and density can be constrained using the energy and shape of the line, respectively. In this source, the line is at the rest-frame energy and the shape is relatively symmetric, which together suggest that the emission comes from relatively optically thin gas that has not been accelerated to high velocities. Together, these diagnostics give one of the most in-depth pictures of supermassive black hole environments to date and will be crucial for testing our models of black hole feeding!
What’s Next?
These XRISM observations are rich with information, and today’s article focused only on the 6.4 keV emission line. The authors are planning a series of further articles, including on the active galactic nucleus winds traced by the absorption lines (i.e., the major dips seen at ~6.7 and ~7 keV in the left panels of Figure 2), comparisons of the emission lines with optical emission lines, and looking for faint evidence of broader emission from even closer to the supermassive black hole. The next obvious steps are also to observe more active galactic nuclei to test whether this multi-zone emission is a common occurrence in active galactic nuclei. One thing’s for sure, this 20/20 vision is sure to reveal new secrets about the lives and environments of supermassive black holes!
Original astrobite edited by Roel Lefever
Editor’s Note: Astrobites is a graduate-student-run organization that digests astrophysical literature for undergraduate students. As part of the partnership between the AAS and astrobites, we occasionally repost astrobites content here at AAS Nova. We hope you enjoy this post from astrobites; the original can be viewed at astrobites.org.
About the author, Megan Masterson:
I’m a 4th-year PhD student at MIT studying transient accretion events around supermassive black holes, including tidal disruption events and changing-look active galactic nuclei. I primarily use multi-wavelength observations to study from the inner accretion flow to the obscuring material in these transients. In my free time, you’ll find me hiking, reading, and watching women’s soccer.
