AAS 242 is nearly here! The AAS Publishing team looks forward to connecting with meeting attendees in Albuquerque, NM, and online, and we’re excited to share a preview of upcoming publishing-related events. Also, be sure to stop by the AAS booth in the Exhibit Hall, which will be staffed by several members of the publishing team, including Julie Steffen (AAS Chief Publishing Officer), Ethan Vishniac (AAS Journals Editor in Chief), Frank Timmes (AAS Journals Associate Editor in Chief), and Gus Muench (AAS Journals Data Editor). We’re also happy to announce that the newest member of the Publishing team, Journals Data Editor Katie Merrell, will be attending the meeting — be sure to stop by and say hello!

AAS Nova Editors Kerry Hensley and Susanna Kohler, AAS Media Fellow Ben Cassese, Astrobites Media Intern Sumeet Kulkarni, and the rest of the Astrobites team will also be available at the Astrobites booth in the Exhibit Hall.

AAS Peer Review Workshop

Sunday, June 4, 8:00 am – 12:00 pm MT

Building on the successes of the first peer review workshop, which was organized by the AAS and IOP Publishing and held remotely in February 2023, the AAS is holding its first-ever in-person peer review training at AAS 242. This workshop, led by the scientific editors of the AAS journals, will teach participants about the peer review process, give them the opportunity to see both poor and exemplary referee reports, and provide them with hands-on experience in writing a peer review report. Participants will receive a graduation certificate.

While signups for this instance of the peer review workshop are closed, more workshops are planned for the future, so keep an eye out for more information about upcoming opportunities!

“The What and Why of Open Science”

Tuesday, June 6, 10:00 – 11:30 am MT | Meeting Room 220

This Meeting-in-a-Meeting will explore the benefits of open science practices, diving into the implementation and impact of creating accessible archives for data and software, making journal articles open access, and much more. Presenters will include AAS Journals Data Editor Gus Muench and program officers from NASA and the National Science Foundation.

Want to learn more about implementing open science practices? A second Meeting-in-a-Meeting taking place on Wednesday, June 7, at 10:00 am MT in Meeting Room 220 will provide opportunities for members of our community to share their experiences, successes, and challenges with open science.

Editor’s Note: This week we’re at the 241st AAS meeting in Seattle, WA, and online. Along with a team of authors from Astrobites, we will be writing updates on selected events at the meeting and posting each day. Follow along here or at astrobites.com for daily summaries, or follow @astrobites on Twitter for live coverage. The usual posting schedule for AAS Nova will resume on January 18th.

Table of Contents:

• Plenary Lecture: John Mather (NASA Goddard Space Flight Center)
• Press Conference: Clouds and Nebulae
• Plenary Lecture: Sangeeta Malhotra (NASA Goddard Space Flight Center)
• Press Conference: Signals from Neutron Stars and Black Holes
• Plenary Lecture: Dan Foreman-Mackey (Flatiron Institute)
• Berkeley Prize Lecture: Anthony Brown (Leiden University)

Plenary Lecture: John Mather (NASA Goddard Space Flight Center) (by Briley Lewis)

John Mather’s plenary was a celebration. He opened by thanking the 8 billion humans on Earth, 10,000 observers, 20,000 engineers, and 100 scientists worldwide for making the huge endeavor of JWST happen, and then took the audience on a whirlwind tour of JWST’s history and the highlights of its first year of discovery. From tracing dark matter to revealing the earliest galaxies, taking photos of planet-forming disks to peering into Titan’s hazy atmosphere, watching an asteroid attack to puzzling over shells around a star, it’s truly been a year of great scientific progress and a whole lot of gorgeous images, too.

Mather also looked towards the future, with shout-outs to so many exciting ongoing projects: Euclid, NGRST, the Vera Rubin Observatory/LSST, thirty-meter class telescopes (TMT, eELT, and GMT), and the Decadal-recommended Habitable Worlds Observatory (also sometimes known as LUVEx, a portmanteau of the telescopes that inspired it — LUVOIR and HabEx). He even speculated beyond that, sharing future concepts like hybrid ground-and-space-based observatories using artificial satellites as orbiting guide stars for adaptive optics systems or as stations for very-long-baseline interferometry (VLBI).

The big takeaway here is that we’ve done some incredible things as a community, and we have so much more to come. “Celebrate, and then write proposals!” he told the astronomers in the audience. “We’re just getting started.”

Live tweets of this session by Briley Lewis.

Return to Table of Contents.

Press Conference: Clouds and Nebulae (by Pratik Gandhi)

One of the final press conferences of the 241st AAS was focused on clouds and nebulae, and by extension supernovae and other processes that lead to the formation of clouds and nebulae.

Dr. Gerrit Verschuur and Dr. Joan Schmelz were first up, showing new results on distance measurements to the high-velocity cloud (HVC) complex M. This year marks the 60th anniversary of the discovery of this HVC in the Milky Way, and its velocity is much higher than the rotational velocity of the galaxy. Their team made the first-ever distance estimate for any HVC, and they found that there is a stream of gas between the star MI and the gas filament (which is now called Complex M). Radio data also shows that there is a large cavity associated with the complex, which appears to be the result of a supernova that exploded 4 million years ago! The team also inferred a distance of 307 parsecs and a total supernova energy output of 3.5 x 10⁵⁰ erg. Finally, they concluded by mentioning that the “Local Chimney,” a low-density extension of the well-known “Local Bubble,” likely came from this progenitor supernova.

Next, Dr. Robert Fesen talked about the exceptional supernova remnant Pa 30. This remnant is really interesting because it was discovered in 2013 by amateur astronomer D. Patchick using data from the WISE mission. In recent years, different teams from Hong Kong, France, and Russia discovered a really unusual massive white dwarf star at the center of the remnant, with some astounding properties like really high-velocity winds and high luminosity. This star could be the product of the merger of two white dwarfs, resulting in a rare Type Iax supernova. The other really fascinating thing about this supernova is that it likely happened only a thousand years ago, which is really recent on galactic timescales!

Dr. Bruce Balick continued the press conference with a talk on “The tempestuous life of the Butterfly Nebula, NGC 6302.” Although his take on it was that it “doesn’t look like much of a butterfly, but rather a dragon sneezing fire all around it.” This nebula is an example of an unexpected stellar evolution result. While most planetary nebulae are symmetrical and formed gently (not from explosions), the Butterfly Nebula is asymmetric, much bigger, and a lot more chaotic. Their team compared Hubble Space Telescope images from 2009 and 2020 and found that there appear to be multiple outflows of gas and other material from the central regions, with different outflows having different directions and different ages. Dr. Balick concluded by saying that observations of the Butterfly Nebula are compatible with a rare triple-star accretion disk model, while single and binary star models are too simplistic to be applicable and do not explain all the observed features.

The final presentation was by Dr. Peter Barnes, who talked about “the case of the masquerading monster in BYF 73.” Cloud BYF 73 is a massive cloud about 8,000 light-years away, with an associated nebula. The mystery associated with it is an inflow of material towards the center, which happens to be the highest rate of mass inflow towards a protostellar object ever seen! Their team used observations from the SOFIA and ALMA observatories, and found strong polarization of magnetic fields in the nebula, and weak polarization in the protostellar core. They also found that the gas infall towards the center is faster than expected, implying a 4–6 times larger protostellar mass than thought, of about 1,000 solar masses. Thus the central protostellar object has been labeled a “masquerading monster”!

Live tweets of this session by Pratik Gandhi.

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Plenary Lecture: Sangeeta Malhotra (NASA Goddard Space Flight Center) (by Isabella Trieweiler)

Dr. Sangeeta Malhotra kicked off her plenary talk, “Tiny Mighty Galaxies,” by promising many vegetable puns and a little bit of science. Dr. Malhotra is a researcher at the NASA Goddard Space Flight Center and works on low mass galaxies. She grew up in Delhi, earned her PhD in Astrophysics from Princeton University (becoming the first woman of color to do so!), and was part of the inaugural class of American Astronomical Society fellows. She was previously a professor at Arizona State University and moved to Goddard to work on the Nancy Grace Roman Telescope (formerly WFIRST).

Dr. Malhotra’s research focuses on Lyman-alpha (Lya) galaxies. The Lyman-alpha line is a spectral line of hydrogen; Lya photons are created when electrons fall from the second energy level down to the ground state. Any star-forming galaxy can make Lya photons, so Lya galaxies are just the particular cases where Lya photons are able to escape the galaxy and be observed. Figuring out exactly what allows Lya to escape some galaxies but not others is an open question. Dr. Malhotra showed that Lya galaxies have some common characteristics — they tend to be small in size, with low metallicity and low dust content. Additionally, many Lya galaxies are young, with low stellar masses but high gas pressure and strong emission lines, hence the label “Tiny Mighty Galaxies.”

Lya galaxies are cosmologically important because they help us understand the process of reionization by providing constraints on the amount of neutral hydrogen present at a given time. Connecting the galaxies with reionization requires a really good understanding of the physics of Lya escape, and that’s where the vegetables come in! Over the course of Galaxy Zoo, a citizen science project tasked to identify and categorize galaxies, members of the public helped find a new kind of galaxy, affectionately named “Green Peas.” Green Pea galaxies are small, round, and green in color, hence the name. They have very strong emission lines, particularly ones produced by oxygen. They also happen to be a very good local universe counterpart to the high-redshift Lya galaxies used for reionization studies. Dr. Malhotra’s group uses Green Peas to test their models of Lya escape and have found that factors such as dust content and peak velocities are some of the best determinants of Lya escape.

The other component needed to connect Lya galaxies and reionization is a large sample of Lya galaxies at high redshift. Dr. Malhotra is working on this via the LAGER survey, which aims to find Lya galaxies at a redshift of 7. The survey is an international collaboration and uses a narrow band approach to identify the bright Lya lines in galaxies. Dr. Malhotra’s involvement in the Roman telescope will also be crucial to reionization research as the telescope’s extremely wide field of view will help astronomers understand how reionization occurs on scales spanning many clusters of galaxies.

[Slide by Sangeeta Malhotra]

Live tweets of this session by Isabella Trierweiler.

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Press Conference: Signals from Neutron Stars and Black Holes (by Graham Doskoch)

The final press conference of AAS241 focused on compact objects: black holes and neutron stars. Four speakers took the podium, presenting discoveries of several new types of astronomical objects — and a couple of old favorites. First up was Prof. Eric Coughlin of Syracuse University. Prof. Coughlin and collaborators studied a tidal disruption event, or TDE, called AT2018fyk. TDEs occur when a supermassive black hole tears apart a nearby star, feasting on its gas and emitting a high-energy outburst. These are usually cataclysmic events, but the group noticed that 600 days after the outburst, AT2018fyk dimmed — and then experienced another, similar outburst 600 days later.

This isn’t supposed to happen with TDEs! The group proposed a model to explain this repetition: a partially disrupted TDE. A star near the supermassive black hole was tidally disrupted, but only partially; some of its gaseous envelope was accreted, leaving a partially-stripped remnant that kept circling the black hole on a 1,200-day orbit. One orbit later, it was once again disrupted. The model predicts that there should be another event this coming August. Will it happen? We’ll have to wait and see.

The next speaker was Emily Engelthaler, of the Center for Astrophysics | Harvard & Smithsonian. She had performed ultraviolet spectroscopy of another TDE (this time not a repeater!). The emission showed a number of expected features, including carbon lines, showing the fast-moving material in the black hole’s accretion disk. What was interesting was the amount of variability, and the eventual disappearance of this carbon emission. Engelthaler proposed that the “puffy doughnut” of material is getting less “puffy,” leading to changes in the spectral absorption and emission.

Engelthaler was followed by Rose Xu, an undergraduate at Bard College. Xu presented results on X-ray flares from Sagittarius A*, the supermassive black hole at the center of the Milky Way. While Sgr A* isn’t as active as many others of its kind, it does exhibit X-ray and infrared flares on a roughly daily basis. Xu was interested in addressing an unresolved question: What’s the mechanism behind these flares? She and her collaborators searched data from the NuSTAR X-ray telescope, discovering seven new flares from 2016 to 2022, including a double-peaked flare. The ground found tentative evidence that bright flares and faint flares may have spectral differences, a hint that they could be caused by different processes.

The final speaker, Dr. Amruta Jaodand of Caltech, presented new results on an unusual pulsar, J1023+0038. Pulsars are the dense, rapidly rotating remains of massive stars, and they emit beams of electromagnetic waves, which sweep across our line of sight, like a lighthouse. This appears as periodic emission, usually at radio wavelengths but occasionally in X-rays and the optical. A subclass of pulsars, millisecond pulsars, spin several hundreds of times per second, after accreting material — and angular momentum — from a companion.

J1023+0038 is a type of millisecond pulsar called a transitional millisecond pulsar. It’s in the process of this accretion, and switches between different modes, one involving X-ray emission and one involving radio emission. Jaodand found that the pulsar also emits ultraviolet pulses; while it’s not the first known UV pulsar, it is the first known UV millisecond pulsar. Coupled with its strange X-ray and radio behavior, this may give insight into pulsar emission mechanisms.

Live tweets of this session by Graham Doskoch.

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Plenary Lecture: Dan Foreman-Mackey (Flatiron Institute) (by Mark Popinchalk)

When Dr. Dan Foreman-Mackey showed a functioning code block on one of his first slides, he whimsically remarked “I don’t think any other plenary has put Python code in their talk,” which was met with a round of laughter. And it’s probably because no other plenary was trying to do what Foreman-Mackey did — spend 40 minutes presenting the motivations, grand ideas, and power of the open source software he’s worked on in his career.

The scientific example that was used was using Gaussian processes to fit a Kepler light curve showing a transiting planet. But that quickly became a background feature to the three Gaussian-process libraries that Foreman-Mackey had created at different stages in his career; george, celerite, and tinygp.

With his natural charm he carefully laid out the major improvements that each of the three packages incorporated into the computation of Gaussian processes. george made a step away from rote implementation, instead offering a library of kernels (tools used to construct the Gaussian-process model). celerite (“Imagine there are accents if you want to pronounce it properly [i.e., celerité]”) used linear algebra to speed up the Gaussian-process calculation, and tinygp used JAX at its core to speed it up even further.

But it wasn’t the technical achievements that were the most impressive. It was the intention behind the packages that truly shined the brightest throughout the plenary. Foreman-Mackey is a champion of open-source software, where the codebase is public, documented, and easily accessible. Some might cringe at the thought of all their work laid bare for anyone to scrutinize. However, it was clear that Foreman-Mackey thought this was a strength. That a code was made for others meant that it needed to be flexible, that public eyes would find the room for improvements and innovations, that there is a strength in trusting the community of your peers.

This wasn’t a plenary on a topic so much as it was a plenary on a way of working. Littered with little jokes, personal anecdotes, and even more lines of code, the talk wasn’t about empowering the audience with knowledge, but encouraging them to try new code and ultimately experience the ecosystem of open-source coding of which Foreman-Mackey is a clear and vocal champion.

Full slide deck: https://speakerdeck.com/dfm/open-software-for-astrophysics-aas241
Live tweets of this session by Mark Popinchalk.

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Berkeley Prize Lecture: Anthony Brown (Leiden University) (by Ali Crisp)

Dr. Anthony Brown gave his plenary on the Gaia mission, for which he and his team were being awarded the AAS Berkeley Prize. He began with an overview of the mission, including a joking remark thanking the JWST team for putting their telescope at L2 (where Gaia is also located) so he doesn’t have to explain what that means in his talks anymore. He emphasized the teamwork aspect of the Gaia mission, listing all the different teams in the Gaia Data Processing and Analysis Consortium (Gaia DPAC) and their contributions to the project.

A group picture of the Gaia collaboration. [Slide by Anthony Brown]

Dr. Brown continued by highlighting Gaia science contributions, starting with providing astrometric measurements of Arrokoth to the New Horizons team, so they could make accurate orbital calculations for the spacecraft’s approach. Gaia data were also used to calculate the precise luminosity functions required to confirm that carbon–oxygen white dwarfs undergo crystallization in their interiors. Gaia’s precise astrometry has also been used to confirm the existence of a black hole, to make 3D maps of nebulae such as Orion, and to build clearer pictures of how different elements are distributed in the Milky Way, which in turn give us a better idea of the galaxy’s formation history.

Dr. Brown ended his talk by listing what new data products will be included in the fourth and fifth Gaia data releases, including updated astrometry, time-series data, and much, much more. He kindly requests that — should you use Gaia data for your research — you give the team credit for their hard work. Specific information on how to acknowledge Gaia can be found here.

Live tweets of this session by Ali Crisp.

Return to Table of Contents.

Editor’s Note: This week we’re at the 241st AAS meeting in Seattle, WA, and online. Along with a team of authors from Astrobites, we will be writing updates on selected events at the meeting and posting each day. Follow along here or at astrobites.com for daily summaries, or follow @astrobites on Twitter for live coverage. The usual posting schedule for AAS Nova will resume on January 18th.

Table of Contents:

• Royal Astronomical Society Gold Medal Lecture: George Efstathiou (University of Cambridge)
• Press Conference: Building Systems in Our Local Universe
• Dannie Heineman Prize Lecture: Norman Murray (CITA)
• STEM Mentorship and Underrepresented Minoritized Students
• Press Conference: Discoveries in the Milky Way’s Backyard and in the Universe at Large
• Plenary Lecture: Chanda Prescod-Weinstein (University of New Hampshire)
• Plenary Lecture: Sabrina Stierwalt (Occidental College)
• Astronomy in Indigenous Communities Special Session [from Tuesday, January 10th]

Royal Astronomical Society Gold Medal Lecture: George Efstathiou (University of Cambridge) (by Yoni Brande)

Professor George Efstathiou is the 2022 Royal Astronomical Society Gold Medal awardee, and as part of this honor, he was invited to give one of the plenary talks here at the winter AAS meeting. Prof. Efstathiou is Professor of Astronomy at the Institute of Astronomy at Cambridge, and he was director of the Institute from 2004 to 2008. His research focuses on cosmology, ranging from simulations of large scale cosmic structure formation to anisotropies in the cosmic microwave background.

Prof. Efstathiou structured his talk around paradigm shifts in cosmology. Fifty-seven years ago, in 1965, Penzias and Wilson discovered the cosmic microwave background (CMB), providing the strongest evidence for the Big Bang theory of the origin of the universe. When Prof. Efstathiou started his PhD a decade later, he worked on early computational models of cosmological structure formation, taking weeks to run on room-sized computers. For comparison, he re-ran some of those models on his laptop, but they only took 30 seconds!

Soon after, inflationary theory was the next paradigm shift in cosmology, which preserved causality in the early universe, linking now-unrelated areas of space with each other just after the universe’s formation. However, while inflation explained the current scale of the fluctuations in the CMB, their origin was still unclear, leading to the development of the modern theory for the quantum generation of those fluctuations, giving modelers initial conditions to tweak for their simulations!

Working from the cold dark matter (CDM) model, Prof. Efstathiou and his group produced a suite of simulations of current-day large scale structure and then conducted a big photometric survey to test their assumptions. They found even more structure in the current universe than they’d predicted, which could only be resolved by a positive cosmological constant, the simplest explanation for dark energy (the Lambda-CDM model).

These theoretical models were quickly tested with even more sophisticated observations, with COBE, WMAP, and Planck measuring the CMB at incredible resolutions, showing spatial invariance and causal connection across the entire sky, with the amplitudes of the fluctuations lending even more support for LCDM and closely matching theoretical predictions.

So, do we actually have a standard model of cosmology? Yes, with some caveats: we don’t really understand inflation, we don’t have a dark matter particle, and we don’t understand dark energy. This raises an uncomfortable question: Is LCDM just a fitting function? Prof. Efstathiou is a bit more optimistic. Each point in the model has lots of indirect observational evidence, so there should be some truth in the model even if we don’t deeply understand the individual ingredients.

A lot of the observational problems need to be resolved. It’s been 25 years since dark energy, the last paradigm shift in cosmology, and who knows where the next one will come from. It’s unlikely that a theorist will come up with something groundbreaking out of nowhere. The Hubble tension still needs to be resolved, and it might be impossible to detect primordial gravitational waves from the CMB. Prof. Efstathiou’s best bet is that the next paradigm shift will be the detection of dark matter. Hopefully, in another 57 years, the RAS Gold Medal winner will step onto the stage at the AAS meeting and give a similar talk, all about how we used to not understand inflation!

Live tweets of this session by Yoni Brande.

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Press Conference: Building Systems in Our Local Universe (by Briley Lewis)

This morning’s press conference tackled the building blocks of our universe, from star-forming regions to planet-forming debris disks — including multiple new exciting results from JWST.

JWST images of the AU Microscopii debris disk. [Kellen Lawson]

Jacob Lustig-Yaeger and Erin May (Johns Hopkins University Applied Physics Laboratory) presented new observations of transiting rocky exoplanet LHS 475b, JWST’s first exoplanet discovery and a previously unconfirmed TESS Object of Interest (TOI). This planet is very similar in size to Earth, but much warmer — and with transmission spectroscopy, they peered into its atmosphere. Its spectrum is remarkably flat, consistent with either a fully carbon dioxide atmosphere or even no atmosphere at all. More observations are needed to figure it out!

A newly revealed image of star-forming region NGC 346 from JWST. [SCIENCE: NASA, ESA, CSA, Olivia C. Jones (UK ATC), Guido De Marchi (ESTEC), Margaret Meixner (USRA)
IMAGE PROCESSING: Alyssa Pagan (STScI), Nolan Habel (USRA), Laura Lenkić (USRA), Laurie E. U. Chu (NASA Ames)]

Ümit Kavak (Universities Space Research Association) continued on the theme of star formation, showing data from the airborne observatory SOFIA that reveal huge outflows from the Trapezium stars within the Orion Nebula moving over 60,000 miles per hour. And last but not least, Theo O’Neill (University of Virginia) displayed a new map of the local bubble’s magnetic field. The local bubble was created a long time ago from supernovae (not from the Sun!), and the Sun just happens to be in the middle of it. This map is going to be a useful new tool for astronomers exploring how magnetic fields affect star formation.

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Dannie Heineman Prize Lecture: Norman Murray (CITA) (by Graham Doskoch)

Here’s a simple question: Why does one day on Earth last 24 hours? That was the focus of the plenary lecture by Prof. Norman Murray, winner of the Dannie Heineman Prize. It might seem easy to answer, but half a century of work has shown it to be anything but. The solution requires an understanding of tidal forces, atmospheric modeling, and a willingness to think about clams.

Prof. Murray took us to the Pacific Northwest. Clams there grow their shells at different rates depending on nutrient and sediment deposition in the shallows of the ocean; if a clam is eating, it’s growing. This in turn is connected to the height of the tides. By looking at the size of bands in a clam’s shell, you can learn about how the tides have varied over time — which in turn tells you about the orbit of the Moon, since it’s one of the two celestial bodies that cause gravitational tides on Earth.

Clams haven’t lived on Earth since the dawn of time, so if you want to go back further, you need to check the geologic record. By probing the composition of strata, you can grab information about the history of Earth’s climate, from which you can in turn extract data showing the precession of Earth and the Moon. More analysis then lets you model the change in the Moon’s semimajor axis.

If that wasn’t complicated enough, Prof. Murray pointed out that there’s another force affecting Earth’s angular momentum: thermal tides. As the Sun heats Earth’s atmosphere, more complex interactions cause changes in pressure, giving rise to a tidal perturbation. In short, gravitational tides from the Moon extract angular momentum from Earth; thermal tides, on the other hand, add angular momentum.

Some fluid dynamics modeling shows how waves can propagate in the atmosphere, driven by these effects. Prof. Murray showed that they’re subject to a particular resonance determined in part by the speed of sound in the atmosphere. This resonance, coupled with thermal and gravitational tides, eventually drove Earth’s angular momentum to its current point, corresponding to a day of roughly 24 hours. The balance has lasted about 1 billion years, give or take.

There are other interesting facts you can derive from modeling; for example, there’s a temperature dependence on all of this. Plus, by simulating the angular momentum transfers, you can model evolution of the Moon’s orbit — in particular, the change in the Moon’s semimajor axis over time. It’s model-dependent, but the results Prof. Murray presents match experimental data points, to varying degrees of success.

The lunar orbital semimajor axis as a function of time. [Slide by Norman Murray]

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STEM Mentorship and Underrepresented Minoritized Students (by Isabella Trierweiler)

This special session included four views on the intersections of mentoring, mental health, and diversity, equity, and inclusion (DEI) work. The first speaker was Jennifer Bates, a social worker and program manager for the Broadening Participation initiative at the National Radio Astronomy Observatory (NRAO). She introduced the motivations for the Broadening Participation Programs, which include five research and mentoring programs to increase representation of students with underrepresented identities in the sciences. She pointed out multiple studies of stress and anxiety amongst college students in general, as well as specifically for BIPOC and LGBTQIA+ students, showing that students or marginalized identities are much more likely to experience discrimination and exclusion but less likely to receive adequate mental health care. Danielle Rowland, who also works on the Broadening Participation Programs at NRAO, then spoke about the NAC (National Astronomy Consortium) program. The program places students into cooperative teams to work on summer research projects. Students also receive mentoring and professional development support and are eligible for further research projects, travel grants, and bridge support for graduate school after their participation in the program.

Timothy Paglione shared his experience running AstroCom NYC, a CUNY program to provide support and mentoring for astrophysics students. The students are paired with research and career mentors and work on research at the American Museum of Natural History. The CUNY system is very extensive, with 25 campuses including senior and community colleges, graduate programs, and professional colleges. The program has grown along with its students’ needs, evolving the approaches to preparing students for graduate school as well as industry jobs and adding a focus on mental health. One of the unique aspects of AstroCom NYC is that the program has a counselor available to serve students’ mental health needs, so that students can attend one-on-one counseling sessions or join a “Solidarity Group.”

Finally, David Morris spoke about his experience growing the physics and astronomy program at the University of Virgin Islands (UVI). UVI is a relatively small university with about 1,500 students, most of whom grew up locally. The degree program in physics, with a concentration in astronomy, just started in 2015 and grew rapidly in its first few years. However, the program faced difficulties when Covid began, and both enrollment in UVI and in the physics program went into a decline. In order to get students involved again and improve recruitment to the physics major, the department started a student-run High Altitude Balloon project. The intensive hands-on experience helped to renew enthusiasm for research amongst the students while giving them the opportunity to work with scientists at other institutions.

Live tweets of this session by Isabella Trierweiler.

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Press Conference: Discoveries in the Milky Way’s Backyard and in the Universe at Large (by Mark Popinchalk)

If you are feeling pedantic, you might point out that a press conference called “Discoveries in the Milky Way’s Backyard and in the Universe at Large,” could be more simply called “Discoveries.” But a better name might have been “Galaxies,” as that was the through line between all the presentations.

First was Burçin Mutlu-Pakdil who announced the discovery of three ultra faint galaxies beyond the local group. Ultra faint dwarf galaxies are the most dark matter dominated objects in the galaxy, but are (by definition) faint and small, which makes them challenging to observe. All the previous examples were around galaxies in our local group (essentially the Milky Way, Andromeda, and smaller friends), but the authors identified three new ones around NGC 253 using Hubble images.

Then Dong-Woo Kim introduced us (or at least me) to XBONGs, X-ray Bright Optically Normal Galaxies. They are just that, galaxy-like objects that look normal in optical light, but are extremely bright in X-ray. By combining Chandra data with objects classified as galaxies in SDSS, they found 820 XBONGs and attempted to understand what they were. 50% of them are almost certainly obscured active galactic nuclei, where the optical light is blocked by gas and dust but the X-ray light is penetrating through. The other half is split between likely being hot gas clouds and maybe diluted active galactic nuclei. In the future, they will use more Chandra observations and double the number of XBONGs (so fun to write) for them to classify, and hopefully understand the phenomenon.

Kaixiang Wang then set about revealing the origin of ultra compact dwarf galaxies (UCDs). These objects seem to blur the definition between globular clusters and dwarf galaxies; they have a similar mass to the latter, but their size is an order of magnitude smaller, closer to the former. One theory is that they are former dwarf galaxies that have had their outer layers stripped by a violent tidal interaction in the past, leaving only the nuclear star cluster. The main result is that they found some objects with tidal disruptions and envelopes — smoking-gun evidence that at least some UCDs originate from disrupted nucleated dwarf galaxies.

We then moved from smaller galaxies to some of the bigger players in our own Local Group, the galaxies that are near the Milky Way. Kat Barger started by warning us about the dangers of supernovae winds pushing out gas in the Large Magellanic Cloud galaxy (LMC). Really the danger is to the LMC, as she showed that the winds were heating up gas and shooting it out of the LMC, at least 4.5 times the amount of gas that the LMC is using to make stars and planets! That’s not necessarily bad for its future star formation rate, as the gas might cool and fall back towards the small galaxy, except there is a much bigger galaxy nearby — our own Milky Way! The presentation ended by showing that there is already a large outflow from the LMC that is being tidally pulled by the Milky Way. Thanks for the gas, LMC!

Finally, Adam Smercina wanted to look at spiral structure in low-mass galaxies, such as the LMC, but it’s not a good example in part because of the tidal influences of the Milky Way. So instead he focused on the Triangulum galaxy, another diminutive neighbor. Using a Hubble survey program called PHATTER, he was able to identify 22 million stars individually, and sort them into rough bins of youngest, young, intermediate and old. When he looked at how those populations were positioned in space, the young stars show a clear spiral structure, while the older ones lose their spiralness! This isn’t necessarily an evolutionary sequence, as the older ones might have been disrupted into their blobby distribution. Rather, it’s more likely a trace of the gas in the galaxy, which behaves differently than the stars do.

Overall it was great to see some new results from galaxies that were indeed in the Milky Way’s backyard and beyond!

Live tweets of this session by Mark Popinchalk.

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Plenary Lecture: Chanda Prescod-Weinstein (University of New Hampshire) (by Isabella Trierweiler)

The theme throughout Dr. Chanda Prescod-Weinstein’s plenary talk was that astrophysics and particle physics will become increasingly entangled as the quest to understand dark matter moves forward. Dr. Prescod-Weinstein is a Professor of Physics and a Core Faculty Member in Women’s and Gender Studies at the University of New Hampshire, and author of the popular science book “The Disordered Cosmos: A Journey into Dark Matter, Spacetime, and Dreams Deferred.” She focused her plenary talk on the role of astrophysics in some of the most pressing open questions regarding dark matter.

Dr. Prescod-Weinstein began her talk by introducing dark matter, the mass that we know is prevalent throughout the universe due to its gravitational influence but which does not seem to be explained by any particles in our current standard model. Astrophysical proof of dark matter has existed for some time — we see it in the flattening of galaxy rotation curves, in lensed galaxies imaged by Hubble and JWST, and in the features of the cosmic microwave background. Based on these observations, and through testing dark matter in cosmological simulations, we know that dark matter doesn’t interact with photons and is cold and slow moving.

She stressed that understanding dark matter is not just a goal for particle physicists — astronomers have stakes in the outcome, too. One of the main examples lies in galaxies, whose formation and evolution is deeply dependent on the dark matter halos they reside in. To truly understand the physics of galaxies and their satellites, we need to understand what dark matter is and how it influences its environment.

Amongst the possible components of dark matter, which span in scale from miniscule particles to multiple-solar-mass black holes, Dr. Prescod Weinstein spoke about two promising options: axions and asymmetric dark matter. Axions are theoretical particles that were proposed to solve symmetry issues in quantum field theory. The particles were proposed in the 1980s, but experiments have just recently become capable of searching for them. The idea behind asymmetric dark matter is that, much like particles and anti-particles, dark matter and anti-dark matter both formed in the universe, and in the process of colliding and annihilating, only dark matter was left to survive to present day.

Venn diagram of the possible theories of dark matter. [Slide by Chanda Prescod-Weinstein]

Illustration of a neutron star’s interior. [Slide by Chanda Prescod-Weinstein]

To move forward in these theories, Dr. Prescod Weinstein emphasized the importance of new instruments such as STROBE-X and the Vera Rubin Observatory. Observations from these telescopes will be crucial in fully utilizing astrophysical probes in the search for dark matter!

Live tweets of this session by Isabella Trierweiler.

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Plenary Lecture: Sabrina Stierwalt (Occidental College)

Dr. Stierwalt began her talk with an overview of dwarf galaxies. She explained that we have recorded evidence of our ancestors observing the Small and Large Magellanic Clouds — two of the most famous dwarf galaxies — dating back to prehistoric times. However, we didn’t know what they or other dwarf galaxies were until Harlow Shapley observed the Sculptor Dwarf Galaxy in 1937.

Moving into the bulk of her talk, Dr. Stierwalt outlined four reasons why dwarf galaxies are both very hard and very important to study:

1. Dwarf galaxies are both small and faint — two characteristics that can greatly limit the observability of an astronomical object. However, because they are small and faint, we can use them to place stricter constraints on galaxy structure. For instance, we know roughly where dwarf galaxies should be in relation to the Milky Way and how many of them there should be, so if we compare the theoretical distribution to what we actually observe, we can determine how much dark matter must be present to reconcile the difference.
2. Dwarf galaxies are strongly affected by stellar feedback because their gravitational wells are shallow. In other words, since they’re smaller than other galaxies, they have less gravity and are more affected by events such as supernovae that create turbulence in the interstellar medium. Studying the effects of stellar feedback can tell us more about both the mechanisms creating the feedback and the structure of the dwarf galaxies themselves. This is especially true in relation to dark matter, since we see dwarf galaxies with both low and high amounts of dark matter, and those with seemingly high amounts of dark matter tend to be more isolated, leading astronomers to wonder if stellar feedback is somehow stripping the dwarf galaxies of dark matter.
3. Dwarf galaxies have low metallicities, so their compositions are similar to those of the highest redshift — i.e., the oldest — galaxies. This similarity means they can give us an idea of how star formation and stellar feedback occurred in the earliest populations. They can also give us insight into how mass loss occurs in low-metallicity stars, and help us discover techniques to find intermediate active galactic nuclei.
4. Dwarf galaxies are heavily influenced by their environment. In other words, they’re very sensitive to what’s happening around them chemically and dynamically. Mergers of dwarf galaxies, for example, are much more likely to occur than mergers of large galaxies, and have different results. Dwarf galaxy mergers have starbursts occurring earlier in the merger than in mergers of larger galaxies, for example, and create more evenly distributed stars.

In closing, Dr. Stierwalt briefly discussed how upcoming surveys with the Rubin Observatory and the Nancy Grace Roman Space Telescope will increase the number of known dwarf galaxies. Additionally, follow-up observations of known dwarf galaxies using JWST will tell us even more about their dynamics and characteristics. Simulations of dwarf galaxy mergers — thought to be the progenitors of larger galaxies such as the Milky Way — are also becoming more and more accurate as we learn more. It’s an exciting time to be studying these small but mighty galaxies!

Live tweets of this session by Ali Crisp.

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Astronomy in Indigenous Communities Special Session [from Tuesday, January 10th](by Macy Huston)

This session was the third of three events at AAS 241 relating to Community Models of Astronomy, following a workshop January 5–6 and the plenary panel on Monday.

Christine Matsuda (Maunakea Observatories) introduced the session, establishing the context of this work from the Astro 2020 decadal survey part 3.4.1. The Community Models of Astronomy workshop focused on strengthening relationships between indigenous communities and the astronomy institutions that exist on their land. The 30-person workshop was hosted by the ‘Imiloa Astronomy Center and Maunakea Observatories, with representation from multiple indigenous communities, as well as indigenous and non-indigenous astronomers and other scientists. Major discussion topics included the difficulty of such relationships, establishing mutual stewardship as opposed to a benefactor/beneficiary relationship, and the misalignment of the pace of this work and institutional timelines. Next steps following the workshop will summarize the ideas discussed and recommendations for the future.

Next, Yuko Kakazu, education and outreach specialist at Thirty Meter Telescope (TMT), spoke about connecting astronomers with Hawaiian students through tutoring. TMT and Mauna Kea have been a source of community division and a symbol of colonialism and injustice since before the 2019 protests. The start of the pandemic in 2020 paused previous interactions. The TMT project manager moved to the community to listen and learn, and a new education and outreach team was established in the area. The pandemic’s impact on education (as Hawaiian schools closed for over a year) saw a decrease in science and math proficiency, particularly among native Hawaiian students and other marginalized groups. The TMT education and outreach group started a tutoring program that reduced the number of students failing classes and helped to establish a sense of community between the astronomers and locals.

The third speaker, Ku’ulei Bezilla (’Imiloa Astronomy Center) presented A Hua He Inoa, which means something like “calling forth a name.” This project at the ‘Imiloa Astronomy Center has worked to reclaim cultural practices in Hawaii, including naming astronomical objects. So far, five student cohorts have gone through the naming process, resulting in six official names: the quasar Pōniuāʻena, the interstellar object ‘Oumuamua, the black hole Pōwehi, the asteroids Kamo’oalewa and Ka’epaoka’āwela, and the dwarf planet Leleākūhonua. The current cohort has submitted the names Leimakua and Kawelo to the 2023 International Astronomical Union ExoWorld naming competition for HAT-P-26 and HAT-P-26b, inspired by a story about family relationships. The group is also working to build an exhibit about light pollution in their community.

The next presentation was about the One Sky Project, given by Ka’iu Kimura (’Imiloa Astronomy Center). This project, which is sponsored by TMT, is bringing together different communities to share stories in planetaria, with the guiding principle: “Everyone sees something a little bit different, but we all see one sky.” Six films have been created so far, based on cultures from Hawai’i, Japan, Navajo, Greece, Canada, and India. The first five films will be released after the final premiere next month, and they will be freely available to planetariums, along with materials to prompt discussion. Ka’iu closed with a mention of the difficulty around this project’s TMT sponsorship given the opposition against its construction on Mauna Kea. But, One Sky Project has appreciated their support and editorial freedom.

The second to last presentation of the session was from Jacelle Ramon-Sauberan. Jacelle is a full-time faculty member at Tohono O’odham Community College who spoke about her work as a part-time communication specialist for NOIRLab/Kitt Peak National Observatory (KPNO). The role provides cultural competency education and helps with relationships between the Tohono O’odham community and KPNO. She showed the new NOIRLab education program logo created by Jeffery Antone Sr., a Tohono O’odham artist. Jacelle also arranged for tribal leaders to visit KPNO for the first time in many years, including Tohono O’odham Nation Chairman Ned Norris Jr., Vice Chairwoman Wavalene Saunders, and Schuk Toak District Leadership. During the Contreras fire at KPNO, the Tohono O’odham nation’s fire department, police, and other entities assisted. Additionally, a medicine person cleansed the mountain and staff after the fire. Jacelle wrapped up with a discussion in-progress updates to KPNO’s land acknowledgement, involving community input, including elders and youths, and translating it to O’odham.

Aparna Venkatesan wrapped up the session with a discussion about the problem of satellite constellations (SatCons). During our ongoing global crises, we have the opportunity to work together and establish better ways of doing things. The SatCon crisis involves the dramatically growing number of satellites in low Earth orbit, threatening astronomy and dark skies everywhere. They cause streaks in images but also contribute to a rise in global brightness, wiping out the “dark sky” regions of the planet. In addition to astronomy, these issues affect cultural sky traditions, human health, and animal behavior, including bird migration. Aparna took part in the Community Engagement working group from the SATCON2 workshop in July 2021. The group examined the future of orbital space in partnerships with indigenous communities, identifying ethical, cultural, and legal issues in the SatCon crisis. She closed with an emphasis on the importance of setting precedents today to work ethically, based on communities, not conquest.

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Editor’s Note: This week we’re at the 241st AAS meeting in Seattle, WA, and online. Along with a team of authors from Astrobites, we will be writing updates on selected events at the meeting and posting each day. Follow along here or at astrobites.com for daily summaries, or follow @astrobites on Twitter for live coverage. The usual posting schedule for AAS Nova will resume on January 18th.

Table of Contents:

• Plenary Lecture: Allison Kirkpatrick (University of Kansas)
• Press Conference: New Developments in the World of Planets
• Plenary Lecture: Nia Imara (University of California, Santa Cruz)
• ExoExplorers Special Session
• Press Conference: Stars and Their Activity
• Henry Norris Russell Lecture: Richard Mushotzky (University of Maryland)
• HEAD Bruno Rossi Prize Lecture: Keith Gendreau and Zaven Arzoumanian (NASA Goddard Space Flight Center)

Plenary Lecture: Allison Kirkpatrick (University of Kansas) (by Yoni Brande)

Everything I Need to Know About AGN I Learned in this Plenary – Allison Kirkpatrick (Univ. Kansas)

Prof. Allison Kirkpatrick is an expert in active galactic nucleus (AGN) observations and is currently a professor at the University of Kansas, where she leads a vibrant research group and heads the KU REU program. Prof. Kirkpatrick is also deeply involved with early JWST AGN science through the JWST Cosmic Evolution Early Release Science (CEERS) collaboration. Astrobites’s live tweeting of her plenary talk can be found here.

Prof. Kirkpatrick began by highlighting her close collaborators, postdocs, and students, without which none of the groundbreaking work happening in her group would be possible.

AGN are the accreting supermassive black holes (SMBHs) at the centers of galaxies. For example, the SMBH in Messier 87, the first target of the Event Horizon Telescope’s imaging campaign, is roughly the size of the solar system (~300 AU), while its host galaxy is more than 10 million times larger. Despite this disparity, SMBHs often have significant impacts on their host galaxies. Observationally, we can see their indirect effects, such as jets and radio lobes, but we can also classify AGN by their direct properties, such as the presence or absence of broad emission lines.

Finding AGN

We can find AGN by observing in several different bands, anything from the X-rays down into the radio. Different parts of the AGN structure (the dusty torus, corona, BH accretion disk, or clouds in the broad and narrow line regions) tend to emit in specific regions of the electromagnetic spectrum. High X-ray emission from the incredibly hot corona is a good specific tracer of AGN, but X-rays are often absorbed by gas in the interstellar medium, making this method relatively incomplete. Cooler temperatures in ionized clouds lead to broad optical emission lines, but can also be obscured, and spectra are expensive. Narrow lines come from the accretion disk, but some (like H-alpha and H-beta) are also characteristic of star formation, requiring specific line ratios to diagnose AGN versus star forming galaxies. The hot dust in the torus is an infrared emitter (with a classic power law), but it needs to be separated from cold dust in the rest of the galaxy. A major benefit is that infrared AGN aren’t obscured by geometry or other structures in the host galaxy. JWST photometry will be able to tease these apart, so stay tuned for new samples of AGN from Prof. Kirkpatrick’s group!

Unification

The observational types of AGN have historically been thought to be geometric effects, where different viewing angles give us clearer or obscured views through the AGN’s own structure down towards the black hole. However, this isn’t the only explanation: non-unified models posit that, for example, high AGN accretion rates can blow the torus further away, removing it as a source of emission entirely. High galaxy masses and mergers can also deliver more obscuring gas into the galaxy, blocking emission from the AGN externally. These processes can also change over a galaxy’s lifetime, where initially obscured AGN may clear away the gas and dust blocking them, eventually transitioning to an unobscured state.

Mergers

When two gas-rich galaxies collide, the merger process compresses their gas and triggers bursts of star formation. In addition, the merger shunts gas towards their centers, massively growing their SMBHs. Recent studies have shown that this gas also obscures the AGN and is correlated with the dust content of the merging galaxies. However, recent studies have also shown that while mergers are sufficient to fuel AGN, they’re not necessary, with half of the observed low redshift quasars in the Stripe82 sample not present in merging galaxies.

Feedback

Strong AGN emission isn’t just a good observational tracer, but it can also drive powerful winds throughout the galaxy. These winds have been theorized to be able to quench star formation, but it’s hard to definitively measure the mass outflows from these winds. Since star formation also consumes lots of gas mass, AGN winds may not actually be sufficient to quench galaxies, especially at high redshift. AGN can also heat dust throughout the rest of the galaxy, and this itself may also be enough to quench star formation. Since dust and gas tend to coincide, AGN-heated gas may also be present, which has been shown observationally. Each of these feedback mechanisms could explain star formation quenching. While this assumes star formation declines in AGN host galaxies, observations of infrared AGN and X-ray AGN imply that both populations may form stars at typical rates.

The Oddballs

Not all AGN are typical or well-behaved. Prof. Kirkpatrick’s group has identified a population they call “Cold Quasars”: high-luminosity AGN with significant amounts of cold gas and lots of dust (but totally unobscured!)

Inclusion

Closing out her plenary, Prof. Kirkpatrick highlighted some major societal concerns in our field. We can’t separate scientists from their science, and who gets to do science is as important as the discoveries they make. Diversity in the field is low, and historical trends have made astronomy a less-than-hospital place for astronomers of marginalized identities, including but not limited to non-white, non-male, neurodivergent, disabled, queer scientists. These scientists often shoulder disproportionate service efforts, are intentionally or implicitly devalued, and have harder times getting funded.

Luckily, this is a solvable problem. There are great resources available to marginalized students to help find their cohorts, including Black in Astro, NSBP, SACNAS, the Astro Outlist, and others! Allies can also do their best to amplify the voices of our marginalized peers, make our conferences and classrooms more inclusive and accessible, value service work alongside research and teaching for hiring, tenure, and funding, educate ourselves on institutional barriers and how to dismantle them, and learn how to mentor all students effectively. Prof. Kirkpatrick closed with a strong statement: “Our field will only be truly accessible when we decide that people matter more than black holes.”

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Press Conference: New Developments in the World of Planets (by Isabella Trierweiler)

Patrick Taylor, discussing radar on the Green Bank Telescope

Patrick Taylor kicked things off by introducing the new radar capabilities of the Green Bank Telescope (GBT). The GBT is currently the world’s largest steerable radio telescope, and it recently got its first prototype radar system, built in collaboration with Raytheon. The new transmitter has less power than a microwave but has already generated some impressive results! To image objects, the GBT works in conjunction with the Very Long Baseline Array (VLBA), with the GBT as a transmitter and VLBA as the receiver. This system resulted in the highest resolution image of the Moon ever taken from Earth, as well as a detailed image of the Tycho crater. The team also demonstrated the GBT transmitter’s use in small-body science by detecting an asteroid five times farther away than the Moon!

Many in the audience were curious about how the GBT system will compare to the recently collapsed Arecibo telescope. Dr. Taylor noted that the GBT is a much smaller telescope, but it does have more flexibility as it is fully steerable (Arecibo had a steerable receiver but the base was built into a sinkhole). He also pointed out the GBT will continue to be used in partnership with the VLBA and eventually the ngVLA. which will bring the whole system’s capabilities in range of Arecibo’s. Designs for the final radar system for the GBT are still in the works, but once the radar system is completed, the GBT could be used for detailed geology and dynamics studies, tracking of space debris and planetary defense, small-body science, and more!

Emily Gilbert, sharing a TESS earth-sized planet in the habitable zone

Emily Gilbert, a postdoc at NASA’s Jet Propulsion Laboratory, presented the exciting discovery of the second known Earth-sized planet in a star’s habitable zone! The habitable zone is the area around a host star that is warm enough for planets to host liquid water. Dr. Gilbert used data from TESS to study the planetary system TOI 700. There were previously three known planets in the system, including planet d, the first Earth-sized planet discovered in the habitable zone. Dr. Gilbert analyzed 14 transits’ worth of data in order to detect the new habitable zone planet, which is slightly smaller than Earth and has an orbital period of 28 days.

TOI 700 is scientifically interesting because the host star is very bright and relatively nearby, and the star appears to be fairly inactive, so it should be a very good candidate for follow up observations! Since the system has planets both within and outside of the habitable zone, detailed studies of this system could help astronomers better understand how planets can follow very different evolutionary tracks after being born in the same protoplanetary disk. Dr. Gilbert says further observations of the system are already in the works! She already has 100 hours on ESPRESSO, a spectrograph at the VLT, to calculate masses for the four planets.

Rob Zellem, announcing the launch of Exoplanet Watch, a citizen science program

Exoplanet Watch is now open to general audiences! The program involves amateur astronomers and members of the general public in the search for exoplanets, with the goal of combining the power of many small telescopes to more efficiently monitor exoplanet transits. Precise transit timings are really crucial for studying exoplanet atmospheres, and now anyone can help out with these studies! Folks with their own telescopes can sign up to contribute data to the project, and anyone without telescope access can help to process the data. All data contributed to the project will be immediately available to everyone, and anyone who volunteers to observe for Exoplanet Watch will be a co-author on any scientific papers that use the data. Exoplanet Watch carried out a test campaign in 2021, combining data from 24 facilities to construct a transit light curve, something that would have taken 2 hours of JWST observing time! Now that the program is open, astronomers will even be able to request observations for particular systems, and will get results more quickly without needing to wait to receive time on a major telescope. The whole system is a really novel way to approach research, allowing astronomers, amateur observers, and the public to all work more closely and collaboratively on astronomy projects. If you would like to get involved in the citizen science project, you can sign up for the Exoplanet Watch Slack here to get started!

Sasha Hinkley, presenting the first directly imaged Gaia Exoplanet

Finally, Sasha Hinkley showed the first direct images of a Gaia Exoplanet, HD206893c. The host star was known to have a circumstellar disk, so it was a promising place to look for exoplanets. The Gaia mission takes very precise measurements of stellar positions in the sky, finding planets based on whether the stars wobble. HD206893 was already known to host one planet, but Gaia data suggested there might be another one, so the team turned to precise imaging to find it. They used the GRAVITY instrument on the VLT to image the system, confirming the orbit of the previously discovered planet and making the discovery of the second planet! The new data is incredibly precise — Dr. Hinkley likens it to observing a dime from 60,000 miles away. The discovered planet is very unique — in size it is right on the border between planets and brown dwarfs (and will hopefully help astronomers better understand the differences between the two groups), and there is evidence that it may have nuclear burning ongoing in the core!

Live tweets for this session by Isabella Trierweiler.

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Plenary Lecture: Nia Imara (University of California, Santa Cruz) (by Pratik Gandhi)

In her tour de force plenary talk, “A Star is Born,” Prof. Nia Imara provided a comprehensive review of the complex and important field of star formation out of molecular clouds, the relevant open questions, and potential resolutions to those questions. Dr. Imara, a professor at UC Santa Cruz, was the first Black woman to get an astrophysics PhD from UC Berkeley, and she is also an artist, community organizer, and founder of the non-profit Onaketa, which provides free STEM tutoring to Black and brown youth. In a fun yet poignant moment, she kicked off her plenary by taking a selfie with the entire audience and then acknowledged her ancestors, family, and teachers/mentors who have guided her over the years.

Molecular clouds are the birthplaces of stars and an important intermediate regime between galaxies and stars. Dr. Imara pointed out how difficult star formation is to fully understand, because it’s a complex, multi-scale process involving many different physical processes like gravity, fluid dynamics, magnetism, and chemistry. Molecular clouds are the first steps in the process of star formation, as the coldest and densest, and thus self-gravitating, regions of the interstellar medium. A typical molecular cloud is composed of atomic hydrogen (HI), molecular hydrogen (H₂), other molecules like carbon monoxide (CO), and dust.

Next, Dr. Imara posed some of the biggest open questions in the field of star formation, such as:

1. How do stellar nurseries form and evolve?
2. What is the role of galaxy environment in star formation?
3. What is the nature of star formation in the early universe?
4. Why do stars have the masses they do?
5. How does star formation depend on the structure of molecular clouds?

A really important idea in the field of star formation is the Kennicutt–Schmidt Law, the idea that star formation rates in galaxies are correlated with the distribution of hydrogen gas in them. Molecular clouds tend to be associated with the highest-surface density of HI gas, and thus are thought to be the setting for most of the star formation in galaxies. Dr. Imara’s work in 2016 implied that turbulence in atomic gas is sub-sonic or trans-sonic, and that HI surface density plays a key role in setting the total mass of molecular clouds. Additionally, although the Kennicutt–Schmidt relation applies to galaxies on large scales, it breaks down when you look at smaller scales. The answer here might lie in cloud ages/lifetimes and whether stellar feedback has had enough time to disperse the cloud after star formation.

Dr. Imara highlighted the PHANGS collaboration, one of the most important surveys of molecular clouds and molecular gas in star-forming galaxies outside of the Milky Way. The image below shows the massive improvement in resolution that PHANGS provides relative to older surveys! One of the key results from PHANGS shows higher surface densities of gas in galactic centers, possibly due to bars funneling gas into the centers. Similarly, PHANGS sees higher gas densities in spiral arms relative to the inter-arm regions.

A slide from Dr. Imara’s plenary talk at AAS 241. Comparing PHANGS survey with previous images, it highlights the increase in spatial resolution. [Adapted from Leroy et al. 2021]

Next, Dr. Imara highlighted the rapid onset of star formation in the early universe, which has been discovered in recent years and was unexpected. ALMA and JWST have observed galaxies at very early times with large masses, lots of dust, and rapid star formation.

On a related note, she highlighted the important concept of the initial mass function (IMF). IMF refers to the distribution of stellar masses at formation, which “impacts nearly every area in astronomy,” says Dr. Imara. Its importance cannot be understated, but we still don’t fully understand all of the ideas behind what causes it! STARFORGE, a suite of cutting-edge simulations of molecular clouds and star formation, has shown that stellar feedback and jets from protostars is crucial for determining the resultant IMF of the stars being born, thus making it a self-regulating process.

Segueing into discussing her recent work, Dr. Imara mentions a major challenge in the field: how do we infer 3D properties of molecular clouds from 2D observations? Well, she and her team had the idea of creating 3D-printed stellar nurseries to visualize the properties of molecular clouds! Dr. Imara is looking at the intersection of art and science to understand how various physical properties affect star formation and the structure of molecular clouds. She and her team ran simulations and then used them to generate the 3D prints. This process helped them determine that what appears to be a gas filament can often be a 3D sheet or pancake-like structure of gas.

In her concluding remarks, Dr. Imara highlighted her nonprofit Onaketa that provides free STEM tutoring to Black and brown children. She also highlights the astronomy that her ancestors and people started studying thousands of years ago. “Star formation provides us with a compelling metaphor — we’re all connected across large scales of space and time,” she concluded.

[Slide by Nia Imara]

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ExoExplorers Special Session (by Briley Lewis)

This afternoon, early career scientists from the NASA ExoExplorers program gathered to discuss their perspectives on diversity, equity, and inclusion efforts in astronomy. These talks explored various dimensions of diversity in astronomy, including race, socio-economic status, disability, gender identity, first-generation status, and more.

Caprice Phillips, graduate student at The Ohio State University and vice president of Black In Astro, shared recent updates on the Black In Astro (BIA) organization and how people can get involved in upcoming events. You may be familiar with BIA from their collaborations with us here at Astrobites! David Coria, graduate student at University of Kansas, highlighted minority-focused academic success programs, including a few important to his career: the K-State Developing Scholars Program, the McNair Postbaccalaureate Program, and the Hagan Scholarship Foundation. Coria recommended that faculty build trust with their students and be understanding of obstacles they have faced, and be willing to take on students from academic success programs.

Kiersten Boley, also a graduate student at The Ohio State University, discussed the classic description of the “pipeline” in academia, suggesting that not only is it leaky, but also that it begins even before college. Income and opportunities for science education are deeply intertwined, and begin affecting kids at a young age — the same young ages when they are forming their science identities. Boley suggested that outreach efforts should target these younger kids at lower-income schools, providing them opportunities they may otherwise not experience.

Dr. Kaitlin Rasmussen (who has been featured before on Astrobites!) explored the experiences of trans, non-binary, and other astronomers beyond the gender binary, as also discussed in their Astro2020 White Paper. Rasmussen listed five flaws in astronomers’ studies of gender in the field: that in these studies gender is white, observable, discrete, a statistic, and inconsequential. They recommend involving sociologists in any studies of gender in the field and compensating marginalized students / colleagues for their expertise on their lived experiences.

UCLA grad student and Astrobites writer Briley Lewis (yep, that’s me!) spoke on disability and accessibility, which Astrobites has great resources on in our Beyond bites. I shared my experiences organizing planetarium shows for Deaf and blind audiences, and with the recent University of California strike. Lastly, UNC Chapel Hill grad student Amy Glazier talked about her experiences as a first-generation college student, and the variety of barriers faced by those without the institutional know-how and lots of unknown unknowns about how to navigate higher education. “Why is it on us to justify our [marginalized students’]presence instead of institutions to justify our absence?” Glazier said. “Stop treating students from marginalized groups as problems, and start treating them as people.”

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Press Conference: Stars and Their Activity (by Macy Huston)

Chih-Chun “Dino” Hsu (Northwestern University) kicked off this afternoon’s press conference with the “Discovery of the Shortest-Period Ultracool Dwarf Binary.” Ultracool dwarfs are low-mass stellar/sub-stellar objects with temperatures below 3000K. Binary systems, particularly those with short periods, are important for creating accurate theoretical models. Only three short-period ultracool dwarf binaries were known before this discovery. Keck observations of the LP 413-53 AB system show a radial velocity signal indicating a 20.5-hour orbital period. This pair’s close-in orbit is comparable to the distance between Jupiter and the Galilean moons. It is unlikely that the objects formed this close together. Two more likely scenarios are orbital evolution and scattering caused by an (ultimately ejected) tertiary companion.

Next up was “To Rain or Not to Rain: Correlating Solar Flare Class and Coronal Rain Statistics” from Kara Kniezewski (United States Naval Academy). Magnetic field line reconnection causes solar flares that heat up plasma, causing it to expand then “rain” back down to the surface. The team analyzed 240 solar flares from 2011 to 2019 (Solar Cycle 24) to track post-flare rain occurrence and duration. The data show a correlation between higher flare strength and higher rain occurrence and duration. They also found that these post-flare rains can predict future solar activity. More powerful flares correspond with higher starspot coverage. While this “rain” effect was known to exist for a while, this work finally examined the issue in detail and established the statistics of post-flare rain in the astrophysical literature.

The third presentation came from Marina Kounkel (Vanderbilt University): “Relating Angular Momentum Evolution and Gyrochronology for Young Stars in the Field.” Stellar ages are typically measured in the context of a cluster of stars that formed together. Based on the population’s evolution, best visualized on an HR diagram, the cluster’s age can be estimated. Gaia has identified thousands of new clusters, allowing for more of this type of study. However, billions of main sequence stars exist in the field, rather than their birth clusters, so we need another method to measure their age. By tracking brightness variability due to starspots, we can measure the rotation periods of stars with telescopes like TESS. With mass and radius data, in addition to period measurements, angular momentum can be estimated. Angular momentum decreases with stellar age, which allows these “gyrochronology” measurements to predict the ages of field stars. This project produced an empirical grid for gyrochronology based on TESS data.

Next, Anastasios Tzanidakis (University of Washington) presented the “Discovery of the Deepest and Longest Known Blinking Giant Star Gaia17bpp.” (Press release) The star’s interesting activity was detected with Gaia, which measures the position and brightness of millions of stars in the galaxy. The cool M-giant star was notable for its odd optical light curve, where it gradually brightened ~4 magnitudes over ~3 years. Archival data back to the 1950s showed a relatively flat light curve for the star until 2013, when it very gradually dimmed. This dramatic dimming event may be explained by a dusty disk eclipsing it, where the disk may host a hot star in its center. If the two stars are gravitationally bound, the orbital period should be ~100–1000 years, so these eclipse events are very rare. This calls back to a similar system, Epsilon Aurigae, which shows dramatic 2-year eclipses every 27 years. These two systems (along with two others) belong to an emerging population of binary stars with dramatic dimming events which future surveys like LSST should help characterize.

The final presentation of this session was “Starspots and Magnetism: Testing the Activity Paradigm in the Pleiades and Messier 67 Star Clusters” from Lyra Cao (The Ohio State University). Cool stars show a lot of magnetic activity and starspots, which can affect their interior structure. In order to create accurate models of these stars, magnetism has to be accounted for. The team developed a method to directly measure the magnetism of stars by separating out the ambient surface and the starspot signatures in their spectra. This allows for magnetic studies in open clusters, where stars all have similar ages and compositions. Rapidly rotating stars show stronger magnetism and starspot coverage, but at a high enough speed, this effect saturates, and starspot levels remain flat. The team found some anomalous stars whose starspot coverage appears too high for their relatively slow rotation periods. When modeling eclipsing binary stars, their radii can appear inflated compared to real radius values. Accounting for starspots can allow for more accurate radius and temperature estimates, which also enables more accurate radius measurements for transiting planets. Starspot activity is most powerful for low-mass stars and stars turning off of the main sequence, then fades away in the stellar evolution process as stars dramatically expand and slow their rotation.

Live-tweet thread by Macy Huston

YouTube recording

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Henry Norris Russell Lecture: Richard Mushotzky (University of Maryland) (by Graham Doskoch)

The Henry Norris Russell Lectureship is presented to an astronomer who has distinguished themself throughout the course of their scientific career. This year’s recipient was Prof. Richard Mushotzky, of the University of Maryland, whose career has paralleled the course of the field he has dedicated his life to: X-ray astronomy. He has seen everything from its serendipitous arrival and exciting early years to the earliest X-ray observatories to the leaps and bounds achieved by the Chandra and XMM-Newton missions. Prof. Mushotzky summarizes where the field is right now as we move into an age of X-ray astronomy heralded by several new instruments.

He began his talk by taking us back to the early days of X-ray astronomy with the launch of the Uhuru satellite. Its X-ray observations gave astronomers a new toy in their toolkit to study active galactic nuclei (AGN), supermassive black holes which are accreting matter and spewing out relativistic jets, high-energy emission, and more. When Uhuru was launched in 1970, AGN were still poorly understood; while we know much more about them today, plenty of questions remain. How are the different kinds of AGN related? How do they interact with their host galaxies? How common are they?

More progress on these problems was made with the HEAO program in the late ‘70s and early ‘80s, which Prof. Mushotzky worked on after finishing graduate school. The HEAO missions studied, among other things, the variability of AGN and were also able to take — in Prof. Mushotzky’s words — “boring” spectra. More progress was made on the spectroscopic front towards the end of the century when Chandra and XMM-Newton launched; over the past couple decades, they have remained stalwarts of the field.

Prof. Mushotzky turned to some of today’s state-of-the-art X-ray astronomy, focusing on the work he and his colleagues have done recently on AGN, much of which has been enabled by the Swift Observatory’s Burst Alert Telescope (BAT). Some of his work has involved studying emission from what are called radio-quiet AGN – many of which can, nevertheless, be detected with radio telescopes like ALMA. Their observations at high frequencies (for radio waves, at least) showed an unexplained component of AGN spectra not easily attributed to known high-energy processes.

They also noticed interesting relationships between active supermassive black holes and their host galaxies. A galaxy is more likely to host an AGN if it contains more molecular gas; conversely, it also turns out that galaxies with AGN are more likely to have large molecular gas reserves. Prof. Mushotzky and collaborators also found that AGN hosts tend to have undergone more mergers with other galaxies; he showed the mosaic below as an example of how spectacular these mergers can be.

Merger remnants, some of which host AGN. [Koss et al. 2010]

Live tweets of this session by Graham Doskoch.

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HEAD Bruno Rossi Prize Lecture: Keith Gendreau and Zaven Arzoumanian (NASA Goddard Space Flight Center) (by Ryan Golant)

Each year, the Bruno Rossi Prize is awarded for “a significant contribution to High Energy Astrophysics, with particular emphasis on recent, original work.” This year, the Rossi Prize was given to Keith Gendreau, Zaven Arzoumanian, and the team responsible for the Neutron Star Interior Composition Explorer (NICER), a revolutionary X-ray telescope launched in 2017. In this plenary lecture, Dr. Gendreau and Dr. Arzoumanian summarized NICER’s capabilities and goals and provided a glimpse into the deluge of fascinating results emerging from NICER’s data.

Dr. Gendreau opened the talk by thanking the whole NICER team, including the nearly 100 scientists in the science working group; later in the talk, Dr. Arzoumanian expressed similar gratitude, stating that “it’s a privilege everyday to work with the talented people who work with NICER.”

Dr. Gendreau’s portion of the talk largely focused on NICER’s unique design specifications. All of NICER’s optics are contained within a small box of roughly one cubic meter, deemed the X-ray Timing Instrument (XTI); the XTI contains 56 densely-arranged concentrator mirrors and sunshades, focusing X-ray emission onto an array of 56 detectors. Since NICER’s original goal was to observe point sources like neutron stars — and not to produce large-area images — the telescope’s instrumentation sacrifices field of view in favor of high throughput and mobility, collecting as many X-ray photons as possible; the XTI can detect individual photons with an energy resolution on par with the best CCD detectors and a time resolution of less than 100 nanoseconds. The XTI is also attached to a highly flexible mount, allowing the instrument to slew quickly and precisely to capture a target’s position down to an arcminute or better.

A detailed schematic diagram of NICER. [Slide by Keith Gendreau]

A view of the Neutron star Interior Composition Explorer (NICER), seen at the center of this image, in its berth on the International Space Station. [NASA]

After reviewing NICER’s key capabilities, Dr. Gendreau passed the mic to Dr. Arzoumanian to talk about NICER’s science results. The initial goal of NICER was to probe the structure, dynamics, and energetics of neutron stars — “the most outrageous objects most people have never heard of.” We currently don’t have a clear picture of what goes on within a neutron star, since the extremely high densities (twice the density of an atomic nucleus) yield matter with exotic properties. However, by measuring the masses and radii of neutron stars (which turns out to be a formidable challenge), one can make inferences regarding the interior composition — stiff cores generally result in larger stars, while fluid cores give smaller stars. By carefully analyzing the X-ray pulses emitted by the millisecond pulsars PSR J0030+0451 and PSR J0740+6620, the NICER team was able to obtain reliable masses and radii for these two neutron stars, thus placing unprecedented constraints on neutron star interiors — favoring a stiff core. Upon the release of NICER’s data on PSR J0030+0451, Nature published an article declaring that “the golden age of neutron-star physics [had]arrived”; with more neutron star measurements on the horizon, NICER should continue to revolutionize our understanding of these compact objects.

A cartoon infographic showing the structure of a neutron star. [NASA’s Goddard Space Flight Center Conceptual Image Lab]

Dr. Gendreau closed the talk with a brief discussion of NICER’s OHMAN (“On-orbit Hookup of MAXI and NICER”) program. As the name suggests, OHMAN couples NICER to JAXA’s MAXI instrument, another payload on the ISS that’s capable of scanning a huge portion of the sky for X-rays; when MAXI picks up a signal, OHMAN tells NICER to slew immediately towards the source, enabling high-resolution detections of fast transient events. Recently, OHMAN proved invaluable in the study of GRB221009A, the most energetic gamma-ray burst ever detected. Dr. Gendreau concluded by remarking that, with the implementation of OHMAN, NICER has become a dynamic partner in our multi-wavelength and multi-messenger exploration of the universe, well in line with the priorities of the Astro2020 decadal survey.

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