245 research outputs found
The Grizzly, December 9, 2021
Bears Walk for Project Healing Hive • Basement Fire in BWC • Phi Psi Fundraiser Gets Messy • Senior Spotlight: Zenya Yanoff • Meet Connor Donovan • Opinions: First Year Check In; Chem Night Exams • Leaving a Player, Returning a Coach • Men and Women\u27s BB Recaphttps://digitalcommons.ursinus.edu/grizzlynews/1976/thumbnail.jp
Galaxy Zoo: kinematics of strongly and weakly barred galaxies
We study the bar pattern speeds and corotation radii of 225 barred galaxies, using integral field unit data from MaNGA and the Tremaine–Weinberg method. Our sample, which is divided between strongly and weakly barred galaxies identified via Galaxy Zoo, is the largest that this method has been applied to. We find lower pattern speeds for strongly barred galaxies than for weakly barred galaxies. As simulations show that the pattern speed decreases as the bar exchanges angular momentum with its host, these results suggest that strong bars are more evolved than weak bars. Interestingly, the corotation radius is not different between weakly and strongly barred galaxies, despite being proportional to bar length. We also find that the corotation radius is significantly different between quenching and star-forming galaxies. Additionally, we find that strongly barred galaxies have significantly lower values for R, the ratio between the corotation radius and the bar radius, than weakly barred galaxies, despite a big overlap in both distributions. This ratio classifies bars into ultrafast bars (R 1.4; 62 per cent). Simulations show that R is correlated with the bar formation mechanism, so our results suggest that strong bars are more likely to be formed by different mechanisms than weak bars. Finally, we find a lower fraction of ultrafast bars than most other studies, which decreases the recently claimed tension with Lambda cold dark matter. However, the median value of R is still lower than what is predicted by simulations
Galaxy Zoo: Kinematics of strongly and weakly barred galaxies
We study the bar pattern speeds and corotation radii of 225 barred galaxies,
using IFU data from MaNGA and the Tremaine-Weinberg method. Our sample, which
is divided between strongly and weakly barred galaxies identified via Galaxy
Zoo, is the largest that this method has been applied to. We find lower pattern
speeds for strongly barred galaxies than for weakly barred galaxies. As
simulations show that the pattern speed decreases as the bar exchanges angular
momentum with its host, these results suggest that strong bars are more evolved
than weak bars. Interestingly, the corotation radius is not different between
weakly and strongly barred galaxies, despite being proportional to bar length.
We also find that the corotation radius is significantly different between
quenching and star forming galaxies. Additionally, we find that strongly barred
galaxies have significantly lower values for R, the ratio between the
corotation radius and the bar radius, than weakly barred galaxies, despite a
big overlap in both distributions. This ratio classifies bars into ultrafast
bars (R < 1.0; 11% of our sample), fast bars (1.0 < R < 1.4; 27%) and slow bars
(R > 1.4; 62%). Simulations show that R is correlated with the bar formation
mechanism, so our results suggest that strong bars are more likely to be formed
by different mechanisms than weak bars. Finally, we find a lower fraction of
ultrafast bars than most other studies, which decreases the recently claimed
tension with {\Lambda}CDM. However, the median value of R is still lower than
what is predicted by simulations.Comment: 20 pages, 16 figure
Galaxy Zoo DESI: Detailed Morphology Measurements for 8.7M Galaxies in the DESI Legacy Imaging Surveys
We present detailed morphology measurements for 8.67 million galaxies in the
DESI Legacy Imaging Surveys (DECaLS, MzLS, and BASS, plus DES). These are
automated measurements made by deep learning models trained on Galaxy Zoo
volunteer votes. Our models typically predict the fraction of volunteers
selecting each answer to within 5-10\% for every answer to every GZ question.
The models are trained on newly-collected votes for DESI-LS DR8 images as well
as historical votes from GZ DECaLS. We also release the newly-collected votes.
Extending our morphology measurements outside of the previously-released
DECaLS/SDSS intersection increases our sky coverage by a factor of 4 (5,000 to
19,000 deg) and allows for full overlap with complementary surveys
including ALFALFA and MaNGA.Comment: 20 pages. Accepted at MNRAS. Catalog available via
https://zenodo.org/record/7786416. Pretrained models available via
https://github.com/mwalmsley/zoobot. Vizier and Astro Data Lab access not yet
available. With thanks to the Galaxy Zoo volunteer
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Transfer learning for galaxy feature detection: Finding giant star-forming clumps in low-redshift galaxies using Faster Region-based Convolutional Neural Network
Giant star-forming clumps (GSFCs) are areas of intensive star-formation that are commonly observed in high-redshift (z ≳ 1) galaxies but their formation and role in galaxy evolution remain unclear. Observations of low-redshift clumpy galaxy analogues are rare but the availability of wide-field galaxy survey data makes the detection of large clumpy galaxy samples much more feasible. Deep Learning (DL), and in particular Convolutional Neural Networks (CNNs), have been successfully applied to image classification tasks in astrophysical data analysis. However, one application of DL that remains relatively unexplored is that of automatically identifying and localizing specific objects or features in astrophysical imaging data. In this paper, we demonstrate the use of DL-based object detection models to localize GSFCs in astrophysical imaging data. We apply the Faster Region-based Convolutional Neural Network object detection framework (FRCNN) to identify GSFCs in low-redshift (z ≲ 0.3) galaxies. Unlike other studies, we train different FRCNN models on observational data that was collected by the Sloan Digital Sky Survey and labelled by volunteers from the citizen science project ‘Galaxy Zoo: Clump Scout’. The FRCNN model relies on a CNN component as a ‘backbone’ feature extractor. We show that CNNs, that have been pre-trained for image classification using astrophysical images, outperform those that have been pre-trained on terrestrial images. In particular, we compare a domain-specific CNN – ‘Zoobot’ – with a generic classification backbone and find that Zoobot achieves higher detection performance. Our final model is capable of producing GSFC detections with a completeness and purity of ≥0.8 while only being trained on ∼5000 galaxy images
Quantifying the Poor Purity and Completeness of Morphological Samples Selected by Galaxy Colour
The galaxy population is strongly bimodal in both colour and morphology, and the two measures correlate strongly, with most blue galaxies being late-types (spirals) and most early-types, typically ellipticals, being red. This observation has led to the use of colour as a convenient selection criteria to make samples which are then labelled by morphology. Such use of colour as a proxy for morphology results in necessarily impure and incomplete samples. In this paper, we make use of the morphological labels produced by Galaxy Zoo to measure how incomplete and impure such samples are, considering optical (ugriz), NUV and NIR (JHK) bands. The best single colour optical selection is found using a threshold of g − r = 0.742, but this still results in a sample where only 56% of red galaxies are smooth and 56% of smooth galaxies are red. Use of the NUV gives some improvement over purely optical bands, particularly for late-types, but still results in low purity/completeness for early-types. No significant improvement is found by adding NIR bands. With any two bands, including NUV, a sample of early-types with greater than two-thirds purity cannot be constructed. Advances in quantitative galaxy morphologies have made colour-morphology proxy selections largely unnecessary going forward; where such assumptions are still required, we recommend studies carefully consider the implications of sample incompleteness/impurity
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Galaxy Zoo: Clump Scout - Design and first application of a two-dimensional aggregation tool for citizen science
Galaxy Zoo: Clump Scout is a web-based citizen science project designed to identify and spatially locate giant star forming clumps in galaxies that were imaged by the Sloan Digital Sky Survey Legacy Survey. We present a statistically driven software framework that is designed to aggregate two-dimensional annotations of clump locations provided by multiple independent Galaxy Zoo: Clump Scout volunteers and generate a consensus label that identifies the locations of probable clumps within each galaxy. The statistical model our framework is based on allows us to assign false-positive probabilities to each of the clumps we identify, to estimate the skill levels of each of the volunteers who contribute to Galaxy Zoo: Clump Scout and also to quantitatively assess the reliability of the consensus labels that are derived for each subject. We apply our framework to a dataset containing 3,561,454 two-dimensional points, which constitute 1,739,259 annotations of 85,286 distinct subjects provided by 20,999 volunteers. Using this dataset, we identify 128,100 potential clumps distributed among 44,126 galaxies. This dataset can be used to study the prevalence and demographics of giant star forming clumps in low-redshift galaxies. The code for our aggregation software framework is publicly available at: https://github.com/ou-astrophysics/BoxAggregato
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