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Here be SDRAGNS! Results from Radio Galaxy Zoo and Hubble’s Zoo Gems
It’s taken a while to get this finished, but I am happy to say that our paper combining Radio Galaxy Zoo and Hubble data on the rare spiral galaxies with large double radio sources (also known as SDRAGNs, Spiral Double Radio AGNs) has been accepted by the Astronomical Journal. The RGZ-HST sample is the largest set of such objects known (we found 15 cases, compared to 11 from everyone else published up through late 2025). With the collaboration of Alexei Moiseev and students using the 6-meter telescope, we could complete the set of redshifts and optical spectroscopic properties for these SDRAGNs
The Zoo Gems project of short-exposure Hubble observations gave us images of 36 potential SDRAGNs. Most of these turned out to be something else – a disturbed but not spiral galaxy, a spiral almost in front of the more distant radio galaxy… Still, we confirmed enough to more than double the known sample of these rare systems from 11 to 26, selected in more systematic ways than their predecessors. As a group, SDRAGNs have a wide range of Hubble types, from Sa to Sc – this was a bit unexpected, since the mass of the central black holes correlates with the bulge starlight, and the radio sources are probably powered by very massive black holes. (Also, another group including Wu, Ho, and Zhuang analyzed many of the Zoo Gems SDRAGN candidates and found that most of them have pseudobulges rather than classical bulges, which suggests that these galaxies have not undergone a major merger over their history). SDRAGN host galaxies are seen nearly edge-on more often than would be expected for a random set of spirals. We do not see many strong interactions, although there are several SDRAGNs with dust lanes twisted out of the galaxy plane which could result from a weak interaction a billion years before our current view. These galaxies occur in denser environments than average as traced by other galaxies, which fits with our understanding of the need to have circumgalactic gas for the radio jets to interact with in order to produce the powerful lobes of radio-emitting material. Combining the radio structures with galaxy properties from the Hubble images, perhaps our key results is that the radio jets merge preferentially within about 30 degrees of the poles of the galaxy disks. This helps understand why the jets make it outside the galaxy – they encounter the least interference from gas within the galaxy that way. This contrasts with the random orientations of those radio jets which happen in spiral Seyfert galaxies, which really do seem to have random directions and mostly dissolve within a few thousand light-years as they encounter the dense gas within the galaxy itself. Returning to the incidence of pseudobulges, within a major merger we expect the black hole to grow by incorporating material from within the galaxy, so it would keep roughly the same “spin” direction as the galaxy disk and impart that to the accretion disk and jets. This directionality seems to be more important than the mass or accretion rate of the black hole in producing SDRAGNs.
As examples of the data we could work with, here is a montage of 9 SDRAGNs using SDSS images overlaid with VLA Sky Survey contours (green) and contours from the lower-frequency LOFAR sky survey (orange). The LOFAR data became available only after the original Radio Galaxy, and are much more sensitive to the diffuse emission from radio lobes.
This montage shows the same nine SDRAGNs in negative views of the Hubble blue-light images. They are oriented so the galaxy plane is horizontal; arrows mark north and are 5 arcseconds long (matching the scale bars on the radio overlays).
Given the roots of Radio Galaxy Zoo and Zoo Gems in the Galaxy Zoo family, it would happen that one of the Hubble targets which turns out to not be a spiral does have a giant emission region similar to Voorwerpjes. We can’t help it, they are everywhere (and from some JWST data, almost everywhen too).
The manuscript is available from the arxiv repository (and from the AJ web site in a couple of months, after formal publication). Much of the text in the first two sections comes from a draft written by the late Jean Tate even before Hubble data started to arrive, and once again we regret that he did not live to see some of the later Hubble images. This was a favorite project of Jean, who managed most of the initial voting to select HST imaging candidates and kept the SDRAGN material in a PBWorks online repository, so well organized that we could reconstruct a great deal of the project detail from there. (The paper includes the master table of all 215 RGZ SDRAGN candidates in case someone else wants to follow them up).
Fresh Paint and Familiar Faces: Updates from Galaxy Zoo
We have two quick but exciting updates to share with the Galaxy Zoo community today!
1. Galaxy Zoo’s updated look
Today, Galaxy Zoo is officially migrating to the Zooniverse’s new frontend codebase. This transition brings a fresh, updated design to our project and a more user-friendly interface for your classifications.
This move won’t affect your existing stats, collections, or favorites. The update is all about making the site faster, more accessible, and easier for our team to maintain in the long run. For a deeper dive into the technical details and what this means for the future of the Zooniverse, check out this post over on the Zooniverse blog.
2. Galaxy Zoo featured in recent ISSI video
During our team meeting at the International Space Science Institute (ISSI) in Bern last year, Galaxy Zoo team members Karen Masters (Galaxy Zoo PI) and Becky Smethurst (Dr. Becky) answered some questions about the project and what our team has been working on in the JWST era. In this short video, they discuss why galaxy morphology is so important for understanding the history of the Universe, our recent Galaxy Zoo efforts with JWST, and the incredible impact your classifications have on our science. Check it out below!
As always, thank you for all your hard work and for being such a vital part of the Galaxy Zoo team.
Happy classifying!
— The Galaxy Zoo Team
Almost 1 Million Classifications on GZ JWST! 🎉
We’re thrilled to share that Galaxy Zoo volunteers are about to reach an incredible milestone: 1,000,000 classifications on GZ JWST!
GZ JWST first launched back in April 2025 with over 300,000 galaxies from the COSMOS-Web survey. In the 200 days since, you have worked through this remarkable dataset at an extraordinary pace, helping us trace how galaxy structures change over cosmic time. Thanks to your classifications, we’re gaining a clearer picture of what galaxies looked like in the early Universe and how their shapes evolved into the systems we see around us today.
Galaxy Zoo has always been powered by the curiosity and dedication of its volunteers. Thank you for donating your time, your attention, and your enthusiasm.
Highlights from Talk
As we celebrate this milestone together, it’s worth taking a moment to look at some of the excitement happening on Talk. These are the top five most-discussed galaxies from this survey, with the images below counting down from #5. Each image links to its Notes page, so check it out and join in.
You can find many more stunning galaxies on Talk. For example, the JWST Gems tag highlights some of the most striking objects volunteers have come across. As always, thank you for making Talk such a joy to explore — it’s a pleasure to see what you all discover. And thank you for helping us (almost) reach one million classifications on GZ JWST! We can’t wait to see what you’ll uncover in the next million. 🎉
Public data release for Galaxy Zoo: Cosmic Dawn!
The below post is by James Pearson (Open University; lead for Galaxy Zoo: Cosmic Dawn data analysis).
We are happy to announce that the classifications for Galaxy Zoo: Cosmic Dawn are now publicly available!
This iteration featured over 41,000 galaxies, using ultra-deep imaging from the Hawaii Twenty Square Degree (H20) survey (a part of the wider Cosmic Dawn survey) to study the Euclid Deep Field North (EDFN), one of the darkest areas of the sky.
More than 10,000 of you contributed almost four million classifications, helping us to find – amongst other things – galaxies with faint (low surface brightness) features and clumps of star formation, as well as more rare objects hidden in this ultra-deep imaging. Your classifications can also help improve the accuracy of machine learning models for faster processing of ever-increasing subject sets, and provide a means of selecting the most interesting objects for further examination with other telescopes. With your help we have already discovered 51 new gravitational lenses – rare phenomena where the light of a distant galaxy is warped into arcs and rings around an intervening galaxy on its path to us, which allow us to study both galaxies in greater detail (in addition to looking pretty!).
This public data release is accompanied by a paper describing the project and some initial analyses of the classifications made by volunteers and by Galaxy Zoo’s machine learning model, Zoobot. You can read the paper (which is under review) on the arXiv at https://arxiv.org/abs/2509.22311.
Thanks again to everyone who contributed their time to making classifications for this project – we really appreciate your participation.
James Pearson, on behalf of the Galaxy Zoo Team
Looking for bars in faraway galaxies
Hi all! My name is Tobias Géron, I’m a postdoctoral researcher at the University of Toronto. I’ve been using Galaxy Zoo for a few years now to study bars in galaxies.
Bars seem to be very common structures in the present-day Universe, with roughly half of all disc galaxies having a bar. Bars are also thought to influence their host galaxies in all kinds of fun ways (e.g. see some previous blogposts here and here). The quintessential barred galaxy is NGC1300, which flaunts a beautiful long bar in its centre that connect to its spiral arms.
As some of you may know, we recently classified images from the CEERS survey in an iteration of Galaxy Zoo called GZ CEERS. These images were taken by JWST, an amazing telescope in space that excels at taking pictures of galaxies that are really far away. Due to the finite nature of the speed of light, looking at faraway galaxies means that we are also looking back in time. Astronomers quantify this with a property called “redshift”. A redshift of 0 corresponds to the present-day Universe, while higher redshifts means looking back further in time. This allows us to study how common bars are over time.
Using data from GZ CEERS, we tried to study bars up to a redshift of 4. This sounds a bit abstract, but it corresponds to looking back roughly 12 billion years in time! The Universe is only ~13.7 billion years old, so we are able to study bars over most of the history of the Universe. How cool is that? Without further ado, here are some cool pictures.
The top row shows galaxies where we found really long and obvious bars. The middle row shows shorter and less obvious bars, while the bottom row shows some unbarred galaxies. My personal favourite is the one in the top-right corner, EGS23205. This galaxy has an absolutely beautiful bar. What’s even crazier is that this galaxy is found at a redshift of ~2, which corresponds to a lookback time of ~10 billion years.
Great – so we now have found bars at high redshifts. However, in order to do some science, we want to know what fraction of galaxies host such bars at any given redshift. This is shown in the image below.
The full black line shows the redshift evolution of the bar fraction found using GZ CEERS. Our bar fractions agree with those obtained from simulations, which are shown with the grey contours (Fragkoudi et al. 2025), as well as some other studies looking at the bar fractions at high redshifts (Le Conte et al. 2024 and Guo et al. 2024). I’ve also added the results of some lower redshift (z < 1) studies to complete the whole picture.
The main conclusion from this plot is that this line is decreasing; i.e. there are fewer bars at higher redshifts. This is consistent with the picture that most galaxies start without a bar. At the highest redshift probed (z = 4), fewer that 5% of disc galaxies have a bar. Over time, more and more galaxies form bars, to such an extent that in the present-day Universe, roughly half of all disc galaxies have a bar!
This has a lot of implications for the evolution of galaxies, as well as the formation and lifetime of the bars themselves. All of this has just recently been published in Géron et al. (2025). We go into much more detail of how the barred galaxies were found, how observational corrections were applied, as well as the implications for galaxy evolution, bar formation and the lifetimes of bars.
In conclusion: bars are awesome. There seem to be a lot of them out there, even at very high redshift. They influence the evolution of galaxies in the local Universe, and are likely a significant contributor to the evolution of galaxies at high redshifts as well. Stay tuned for more exciting upcoming results from GZ CEERS!
Cheers,
Tobias
Announcing the Galaxy Zoo JWST project!
We are thrilled to announce the launch of the Galaxy Zoo JWST project, with ~300,000 galaxy images from the COSMOS-Web survey taken with NASA’s James Webb Space Telescope (JWST)! We now need your help identifying the shapes of these galaxies by classifying them on Galaxy Zoo. These classifications will help scientists answer questions about how the shapes of galaxies have changed over time, and what caused these changes and why.
As we look at more distant objects in the Universe, we see them as they were billions of years ago because light takes time to travel to us. With JWST able to spot galaxies at greater distances than ever before, we’re seeing what galaxies looked like early in the Universe for the first time. The shape of the galaxies we see then tells us about what a galaxy has been through in its lifetime: how it was born, how and when it has formed stars, and how it has interacted with its neighbours. By looking at how galaxy shapes change with distance away from us, we can work out which processes were more common at different times in the Universe’s history.
Image credit: COSMOS-Web / Kartaltepe / Casey / Franco / Larson / RIT / UT Austin / CANDIDE.
Now, with data from JWST, we’re able to look deeper into the cosmos and further back in cosmic time than ever before, investigating the wild and wonderful ancestors of the Milky Way and the galaxies which surround us in today’s Universe. Thanks to the light collecting power of JWST, there are now over 300,000 images of galaxies on the Galaxy Zoo website that need your help to classify their shapes. If you’re quick, you may even be the first person to see the distant galaxies you’re asked to classify. You will be asked several questions, such as ‘Is the galaxy round?’, or ‘Are there signs of spiral arms?’. These classifications are not only useful for the scientific questions we want to answer now, but also as a training set for Artificial Intelligence (AI) algorithms. Without being taught what to look for by humans, AI algorithms struggle to classify galaxies. But together, humans and AI can accurately classify limitless numbers of galaxies.
We here at Galaxy Zoo have developed our own AI algorithm called ZooBot (see this previous blog post for more detail), which will sift through the JWST images first and label the ‘easier ones’ where there are many examples that already exist in previous images from the Hubble Space Telescope. When ZooBot is not confident on the classification of a galaxy, perhaps due to complex or faint structures, it will show it to users on Galaxy Zoo to get their human classifications, which will then help ZooBot to learn more.
You might also notice a slight difference to the classification interface for this project. Each image has two main colour versions available to help you see different features in the galaxy. Both of these colours images are built from the four COSMOSweb filters (F115W, F150W, F277W, and F444W) but with two different scalings. On the right the scaling is set to reveal bright central features more clearly, while the lefthand version should reveal fainter outskirts. You can also see the original four single filter images if you’d like in the flip book (see the two circles below the centre of the two images). By providing all of these images we’re hoping that it’ll be easier for volunteers to classify the images, and allow us to extract the most information about a galaxy from each image.
We’re really excited about this project on the team, not least because it’s been in the pipeline for a long time! We have had two team meetings at the International Space Science Institute (ISSI) in Bern, Switzerland over the past year in preparation for this launch, so it’s great to be finally at this point. We’re particularly excited though because of the science that will be made possible thanks to this project. Given JWST’s incredible sensitivity to light (thanks to that beautifully large mirror!), we’ll be able to classify the shapes of galaxies out to much greater distances than ever before. This means we can see further back in time in the Universe’s history to trace how the shapes of galaxies have changed earlier in cosmic time. We’ve already taken a look at your classifications from the pilot JWST project we ran on ~9000 galaxy images from the CEERS survey (another JWST galaxies survey, that’s smaller then COSMOS-Web that’s launching today) and with your help we found disk galaxies and galaxies with bars out to greater distances than ever before. So with even more JWST galaxies now on the site, all of us on the team are buzzing with excitement thinking of all the new discoveries coming our way soon.
If you do decide to take part: THANK YOU! We appreciate every single click. Join us and classify now.
Galaxy Zoo in Japanese
この度、Galaxy Zooは日本語でも参加できるようになりました(すでに中国語、フランス語、スペイン語、ハンガリー語、そして英語で利用できます)。ボランティアの翻訳者である @InoSenpai (イノ先輩)に感謝します。これで、本プロジェクトを日本語話者にも広めていけるようになりました。
We’re delighted to share that Galaxy Zoo is now available in Japanese (in addition to Chinese, French, Spanish, Hungarian and English). Thanks to the efforts of volunteer translator @InoSenpai we can now bring Galaxy Zoo to a wider audience of Japanese speakers.
Galaxy Zoo featured in first Euclid data release!
We’re delighted to share that Galaxy Zoo (and you!) are featured in the first Euclid data release announced today!
Back in August 2024, we launched an intensive Euclid campaign where 9,976 of you classified over 380,000 galaxies. Thanks to your hard work and efforts, you trained the newest iteration of Zoobot and powered the first Euclid data release! Read the paper here.
Thanks again for your participation and help making this science possible!
Galaxy Zoo Team
Cosmic Disco: Help us characterize galaxy merger stages!
You have helped classify the morphologies of millions of galaxies through various Galaxy Zoo campaigns! Among those several millions are colliding galaxies (aka galaxy mergers) that are experiencing a significant change in their morphology and physical nature. Previously you have answered questions about the presence of disturbed morphological features (e.g., major or minor disturbance). As the process of galaxy merging can take several millions to a billion years, the merging galaxies we observe present to us in a plethora of configurations depending on their merging stage.
Identifying the stage of merging can help us better associate the impact of mergers to specific changes in the galaxy properties. An alternative approach is to use the disturbed morphological signatures (also called tidal features) as a proxy for merger staging. We are launching a new project Cosmic Disco: Characterizing Galaxy Collisions where you can help characterize the images containing mergers into objective categories.
We are looking forward to doing awesome science with your help! Happy Classifying!
Letting Things Slide: A New Trial Interface for Expressing Uncertainty
“How many spiral arms are in the image – is it two or three? Is that a disk viewed edge-on? I think so, but I’m not quite sure…” If you’ve interacted with Galaxy Zoo before, you may have asked yourself questions like these. Real galaxy images can be confusing. You may be uncertain!
Until now, you have always had to make a choice. There was no way to express uncertainty in your annotations. But now there is! Try it here.
We are trialing a new experimental interface that lets you express your confidence in your annotations by dragging on a slider. This design is motivated by recent research indicating that we may be able to learn more, faster, by collecting annotator uncertainty [see this paper, this paper, this paper, this paper]. Allowing you to express your uncertainty by dragging a slider means that you – Zooniverse Friend – are providing more information with each click.
We believe this slider design might help us – through your support – discover more about galaxies, faster!
This is the second trial project we’re starting, adding to the Tags trial that Hayley introduced earlier on the blog. The big picture here is that we’re trying to think about how Galaxy Zoo could evolve in the coming years. As with any science project, we need to gather data and test our ideas.
Join in here and help us improve Galaxy Zoo.
We’ll run this trial for a short time – perhaps a couple of months – to gather your annotations and feedback. You can still use the current Galaxy Zoo that you know and (hopefully) love, at www.galaxyzoo.org.
Thank you for helping us,
Mike, Katie, and Ilia.
Galaxy Zoo 