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Black Hole

Lensing of space time around a black hole. At Oxford we study black holes observationally and theoretically on all size and time scales - it is some of our core work.

Credit: ALAIN RIAZUELO, IAP/UPMC/CNRS. CLICK HERE TO VIEW MORE IMAGES.

Prof Chris Lintott

Professor of Astrophysics and Citizen Science Lead

Research theme

  • Astronomy and astrophysics

Sub department

  • Astrophysics

Research groups

  • Zooniverse
  • Beecroft Institute for Particle Astrophysics and Cosmology
  • Rubin-LSST
chris.lintott@physics.ox.ac.uk
Telephone: 01865 (2)73638
Denys Wilkinson Building, room 532C
www.zooniverse.org
orcid.org/0000-0001-5578-359X
  • About
  • Citizen science
  • Group alumni
  • Publications

Zooniverse labs

Zooniverse lab
Build your own Zooniverse project

The Zooniverse lab lets anyone build their own citizen science project

Zooniverse Lab

Galaxy Zoo CEERS: Bar Fractions Up to z ∼ 4.0

The Astrophysical Journal American Astronomical Society 987:1 (2025) 74

Authors:

Tobias Géron, RJ Smethurst, Hugh Dickinson, LF Fortson, Izzy L Garland, Sandor Kruk, Chris Lintott, Jason Shingirai Makechemu, Kameswara Bharadwaj Mantha, Karen L Masters, David O’Ryan, Hayley Roberts, BD Simmons, Mike Walmsley, Antonello Calabrò, Rimpei Chiba, Luca Costantin, Maria R Drout, Francesca Fragkoudi, Yuchen Guo, BW Holwerda, Shardha Jogee, Anton M Koekemoer, Ray A Lucas

Abstract:

We study the evolution of the bar fraction in disk galaxies between 0.5 < z < 4.0 using multiband colored images from JWST Cosmic Evolution Early Release Science Survey (CEERS). These images were classified by citizen scientists in a new phase of the Galaxy Zoo (GZ) project called GZ CEERS. Citizen scientists were asked whether a strong or weak bar was visible in the host galaxy. After considering multiple corrections for observational biases, we find that the bar fraction decreases with redshift in our volume-limited sample (n = 398); from 25−4+6 % at 0.5 < z < 1.0 to 3−1+6 % at 3.0 < z < 4.0. However, we argue it is appropriate to interpret these fractions as lower limits. Disentangling real changes in the bar fraction from detection biases remains challenging. Nevertheless, we find a significant number of bars up to z = 2.5. This implies that disks are dynamically cool or baryon dominated, enabling them to host bars. This also suggests that bar-driven secular evolution likely plays an important role at higher redshifts. When we distinguish between strong and weak bars, we find that the weak bar fraction decreases with increasing redshift. In contrast, the strong bar fraction is constant between 0.5 < z < 2.5. This implies that the strong bars found in this work are robust long-lived structures, unless the rate of bar destruction is similar to the rate of bar formation. Finally, our results are consistent with disk instabilities being the dominant mode of bar formation at lower redshifts, while bar formation through interactions and mergers is more common at higher redshifts.
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Accelerating Long-period Exoplanet Discovery by Combining Deep Learning and Citizen Science

Astronomical Journal American Astronomical Society 170:1 (2025) 39

Authors:

Shreshth A Malik, Nora L Eisner, Ian R Mason, Sofia Platymesi, Suzanne Aigrain, Stephen J Roberts, Yarin Gal, Chris J Lintott

Abstract:

Automated planetary transit detection has become vital to identify and prioritize candidates for expert analysis and verification given the scale of modern telescopic surveys. Current methods for short-period exoplanet detection work effectively due to periodicity in the transit signals, but a robust approach for detecting single-transit events is lacking. However, volunteer-labeled transits collected by the Planet Hunters TESS (PHT) project now provide an unprecedented opportunity to investigate a data-driven approach to long-period exoplanet detection. In this work, we train a 1D convolutional neural network to classify planetary transits using PHT volunteer scores as training data. We find that this model recovers planet candidates (TESS objects of interest; TOIs) at a precision and recall rate exceeding those of volunteers, with a 20% improvement in the area under the precision-recall curve and 10% more TOIs identified in the top 500 predictions on average per sector. Importantly, the model also recovers almost all planet candidates found by volunteers but missed by current automated methods (PHT community TOIs). Finally we retrospectively utilise the model to simulate live deployment in PHT to reprioritize candidates for analysis. We also find that multiple promising planet candidates, originally missed by PHT, would have been found using our approach, showing promise for upcoming real-world deployment.
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Galaxy Zoo JWST: Up to 75% of discs are featureless at 3 < z < 7

Monthly Notices of the Royal Astronomical Society (2025) staf506

Authors:

RJ Smethurst, BD Simmons, T Géron, H Dickinson, L Fortson, IL Garland, S Kruk, SM Jewell, CJ Lintott, JS Makechemu, KB Mantha, KL Masters, D O’Ryan, H Roberts, MR Thorne, M Walmsley, M Calabrò, B Holwerda, JS Kartaltepe, AM Koekemoer, Y Lyu, R Lucas, F Pacucci, M Tarrasse
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Galaxy Zoo JWST: Up to 75% of discs are featureless at $3

(2025)

Authors:

RJ Smethurst, BD Simmons, T Géron, H Dickinson, L Fortson, IL Garland, S Kruk, SM Jewell, CJ Lintott, JS Makechemu, KB Mantha, KL Masters, D O'Ryan, H Roberts, MR Thorne, M Walmsley, M Calabrò, B Holwerda, JS Kartaltepe, AM Koekemoer, Y Lyu, R Lucas, F Pacucci, M Tarrasse
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Details from ArXiV

Finding radio transients with anomaly detection and active learning based on volunteer classifications

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 538:3 (2025) staf336

Authors:

Alex Andersson, Chris Lintott, Rob Fender, Michelle Lochner, Patrick Woudt, Jakob van den Eijnden, Alexander van der Horst, Assaf Horesh, Payaswini Saikia, Gregory R Sivakoff, Lilia Tremou, Mattia Vaccari

Abstract:

<jats:title>ABSTRACT</jats:title> <jats:p>In this work, we explore the applicability of unsupervised machine learning algorithms to finding radio transients. Facilities such as the Square Kilometre Array (SKA) will provide huge volumes of data in which to detect rare transients; the challenge for astronomers is how to find them. We demonstrate the effectiveness of anomaly detection algorithms using 1.3 GHz light curves from the SKA precursor MeerKAT. We make use of three sets of descriptive parameters (‘feature sets’) as applied to two anomaly detection techniques in the astronomaly package and analyse our performance by comparison with citizen science labels on the same data set. Using transients found by volunteers as our ground truth, we demonstrate that anomaly detection techniques can recall over half of the radio transients in the 10 per cent of the data with the highest anomaly scores. We find that the choice of anomaly detection algorithm makes a minor difference, but that feature set choice is crucial, especially when considering available resources for human inspection and/or follow-up. Active learning, where human labels are given for just 2 per cent of the data, improves recall by up to 20 percentage points, depending on the combination of features and model used. The best-performing results produce a factor of 5 times fewer sources requiring vetting by experts. This is the first effort to apply anomaly detection techniques to finding radio transients and shows great promise for application to other data sets, and as a real-time transient detection system for upcoming large surveys.</jats:p>
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