Your search keyword '"Lintott, C."' showing total 10 results

1. Supermassive black holes in merger-free galaxies have higher spins which are preferentially aligned with their host galaxy.

Author

Beckmann, R S, Smethurst, R J, Simmons, B D, Coil, A, Dubois, Y, Garland, I L, Lintott, C J, Martin, G, Peirani, S, and Pichon, C

Subjects

SUPERMASSIVE black holes, GALAXY mergers, GALACTIC nuclei, GALAXIES, ACTIVE galactic nuclei, GALACTIC bulges

Abstract

Here, we use the Horizon–active galactic nucleus (AGN) simulation to test whether the spins of supermassive black hole (SMBH) in merger-free galaxies are higher. We select samples using an observationally motivated bulge-to-total mass ratio of <0.1, along with two simulation-motivated thresholds selecting galaxies which have not undergone a galaxy merger since z  = 2, and those SMBHs with |$\lt 10~{{\ \rm per\ cent}}$| of their mass due to SMBH mergers. We find higher spins (>5σ) in all three sample compared to the rest of the population. In addition, we find that SMBHs with their growth dominated by BH mergers following galaxy mergers are less likely to be aligned with their galaxy spin than those that have grown through accretion in the absence of galaxy mergers (3.4σ). We discuss the implications this has for the impact of active galactic nucleus (AGN) feedback, finding that merger-free SMBHs spend on average 91 per cent of their lifetimes since z  = 2 in a radio mode of feedback (88 per cent for merger-dominated galaxies). Given that previous observational and theoretical works have concluded that merger-free processes dominate SMBH-galaxy co-evolution, our results suggest that this co-evolution could be regulated by radio mode AGN feedback. [ABSTRACT FROM AUTHOR]

Published

2024

2. Evidence for non-merger co-evolution of galaxies and their supermassive black holes.

Author

Smethurst, R J, Beckmann, R S, Simmons, B D, Coil, A, Devriendt, J, Dubois, Y, Garland, I L, Lintott, C J, Martin, G, and Peirani, S

Subjects

GALAXY mergers, SUPERMASSIVE black holes, GALAXIES, COEVOLUTION, GALACTIC bulges, STELLAR mass, GALACTIC evolution

Abstract

Recent observational and theoretical studies have suggested that supermassive black holes (SMBHs) grow mostly through non-merger ('secular') processes. Since galaxy mergers lead to dynamical bulge growth, the only way to observationally isolate non-merger growth is to study galaxies with low bulge-to-total mass ratio (e.g. |$B/T\lt 10~{{\ \rm per\ cent}}$|⁠). However, bulge growth can also occur due to secular processes, such as disc instabilities, making disc-dominated selections a somewhat incomplete way to select merger-free systems. Here we use the Horizon-AGN simulation to select simulated galaxies which have not undergone a merger since z = 2, regardless of bulge mass, and investigate their location on typical black hole-galaxy scaling relations in comparison to galaxies with merger dominated histories. While the existence of these correlations has long been interpreted as co-evolution of galaxies and their SMBHs driven by galaxy mergers, we show here that they persist even in the absence of mergers. We find that the correlations between SMBH mass and both total mass and stellar velocity dispersion are independent of B/T ratio for both merger-free and merger-dominated galaxies. In addition, the bulge mass and SMBH mass correlation is still apparent for merger-free galaxies, the intercept for which is dependent on B/T. Galaxy mergers reduce the scatter around the scaling relations, with merger-free systems showing broader scatter. We show that for merger-free galaxies, the co-evolution is dominated by radio-mode feedback, and suggest that the long periods of time between galaxy mergers make an important contribution to the co-evolution between galaxies and SMBHs in all galaxies. [ABSTRACT FROM AUTHOR]

Published

2024

3. SDSS-IV MaNGA: the different quenching histories of fast and slow rotators.

Author

Smethurst, R. J., Masters, K. L., Lintott, C. J., Weijmans, A., Merrifield, M., Penny, S. J., Aragón-Salamanca, A., Brownstein, J., Bundy, K., Drory, N., Law, D. R., and Nichol, R. C.

Subjects

GALAXIES, ASTRONOMY, STAR formation, STELLAR evolution

Abstract

Do the theorized different formation mechanisms of fast and slow rotators produce an observable difference in their star formation histories? To study this, we identify quenching slow rotators in the MaNGA sample by selecting those that lie below the star-forming sequence and identify a sample of quenching fast rotators that were matched in stellar mass. This results in a total sample of 194 kinematically classified galaxies, which is agnostic to visual morphology. We use u - r and NUV - u colours from the Sloan Digital Sky Survey and GALEX and an existing inference package, STARPY, to conduct a first look at the onset time and exponentially declining rate of quenching of these galaxies. An Anderson-Darling test on the distribution of the inferred quenching rates across the two kinematic populations reveals they are statistically distinguishable (3.2σ). We find that fast rotators quench at a much wider range of rates than slow rotators, consistent with a wide variety of physical processes such as secular evolution, minor mergers, gas accretion and environmentally driven mechanisms. Quenching is more likely to occur at rapid rates (τ ≲ 1Gyr) for slow rotators, in agreement with theories suggesting slow rotators are formed in dynamically fast processes, such as major mergers. Interestingly, we also find that a subset of the fast rotators quench at these same rapid rates as the bulk of the slow rotator sample. We therefore discuss how the total gas mass of a merger, rather than the merger mass ratio, may decide a galaxy's ultimate kinematic fate. [ABSTRACT FROM AUTHOR]

Published

2018

4. Galaxy Zoo: evidence for rapid, recent quenching within a population of AGN host galaxies.

Author

Smethurst, R. J., Lintott, C. J., Simmons, B. D., Schawinski, K., Bamford, S. P., Cardamone, C. N., Kruk, S. J., Masters, K. L., Urry, C. M., Willett, K. W., and Wong, O. I.

Subjects

*GALACTIC nuclei, *GALAXIES, *BLACK holes, *CLASSIFICATION of galaxies, *GRAVITATIONAL interactions

Abstract

We present a population study of the star formation history of 1244 Type 2 active galactic nuclei (AGN) host galaxies, compared to 6107 inactive galaxies. A Bayesian method is used to determine individual galaxy star formation histories, which are then collated to visualize the distribution for quenching and quenched galaxies within each population.We find evidence for some of the Type 2 AGN host galaxies having undergone a rapid drop in their star formation rate within the last 2 Gyr. AGN feedback is therefore important at least for this population of galaxies. This result is not seen for the quenching and quenched inactive galaxies whose star formation histories are dominated by the effects of downsizing at earlier epochs, a secondary effect for the AGN host galaxies. We show that histories of rapid quenching cannot account fully for the quenching of all the star formation in a galaxy's lifetime across the population of quenched AGN host galaxies, and that histories of slower quenching, attributed to secular (non-violent) evolution, are also key in their evolution. This is in agreement with recent results showing that both merger-driven and non-merger processes are contributing to the co-evolution of galaxies and supermassive black holes. The availability of gas in the reservoirs of a galaxy, and its ability to be replenished, appear to be the key drivers behind this co-evolution. [ABSTRACT FROM AUTHOR]

Published

2016

5. Galaxy Zoo: evidence for diverse star formation histories through the green valley.

Author

Smethurst, R. J., Lintott, C. J., Simmons, B. D., Schawinski, K., Marshall, P. J., Bamford, S., Fortson, L., Kaviraj, S., Masters, K. L., Melvin, T., Nichol, R. C., Skibba, R. A., and Willett, K. W.

Subjects

*GALAXIES, *STELLAR evolution, *PREDICTION models, *ULTRAVIOLET radiation, *PROBABILITY theory

Abstract

Does galaxy evolution proceed through the green valley via multiple pathways or as a single population? Motivated by recent results highlighting radically different evolutionary pathways between early- and late-type galaxies, we present results from a simple Bayesian approach to this problem wherein we model the star formation history (SFH) of a galaxy with two parameters, [t, τ ] and compare the predicted and observed optical and near-ultraviolet colours. We use a novel method to investigate the morphological differences between the most probable SFHs for both disc-like and smooth-like populations of galaxies, by using a sample of 126 316 galaxies (0.01 < z <0.25) with probabilistic estimates of morphology from Galaxy Zoo. We find a clear difference between the quenching time-scales preferred by smooth- and disc-like galaxies, with three possible routes through the green valley dominated by smooth- (rapid time-scales, attributed to major mergers), intermediate- (intermediate time-scales, attributed to minor mergers and galaxy interactions) and disc-like (slow time-scales, attributed to secular evolution) galaxies.We hypothesize that morphological changes occur in systems which have undergone quenching with an exponential time-scale τ < 1.5Gyr, in order for the evolution of galaxies in the green valley to match the ratio of smooth to disc galaxies observed in the red sequence. These rapid time-scales are instrumental in the formation of the red sequence at earlier times; however, we find that galaxies currently passing through the green valley typically do so at intermediate time-scales. [ABSTRACT FROM AUTHOR]

Published

2015

6. Galaxy Zoo: the properties of merging galaxies in the nearby Universe – local environments, colours, masses, star formation rates and AGN activity.

Author

Darg, D. W., Kaviraj, S., Lintott, C. J., Schawinski, K., Sarzi, M., Bamford, S., Silk, J., Andreescu, D., Murray, P., Nichol, R. C., Raddick, M. J., Slosar, A., Szalay, A. S., Thomas, D., and Vandenberg, J.

Subjects

GALAXIES, STAR formation, ASTRONOMY, ELLIPTICAL galaxies, STELLAR evolution

Abstract

Following the study of Darg et al., we explore the environments, optical colours, stellar masses, star formation and active galactic nucleus activity in a sample of 3003 pairs of merging galaxies drawn from the Sloan Digital Sky Survey using visual classifications from the Galaxy Zoo project. While Darg et al. found that the spiral-to-elliptical ratio in (major) mergers appeared higher than that of the global galaxy population, no significant differences are found between the environmental distributions of mergers and a randomly selected control sample. This makes the high occurrence of spirals in mergers unlikely to be an environmental effect and must therefore arise from differing time-scales of detectability for spirals and ellipticals. We find that merging galaxies have a wider spread in colour than the global galaxy population, with a significant blue tail resulting from intense star formation in spiral mergers. Galaxies classed as star-forming using their emission-line properties have average star formation rates approximately doubled by the merger process though star formation is negligibly enhanced in merging elliptical galaxies. We conclude that the internal properties of galaxies significantly affect the time-scales over which merging systems can be detected (as suggested by recent theoretical studies) which leads to spirals being ‘over-observed’ in mergers. We also suggest that the transition mass , noted by Kauffmann et al., below which ellipticals are rare could be linked to disc survival/destruction in mergers. [ABSTRACT FROM AUTHOR]

Published

2010

7. Galaxy Zoo: the fraction of merging galaxies in the SDSS and their morphologies.

Author

Darg, D. W., Kaviraj, S., Lintott, C. J., Schawinski, K., Sarzi, M., Bamford, S., Silk, J., Proctor, R., Andreescu, D., Murray, P., Nichol, R. C., Raddick, M. J., Slosar, A., Szalay, A. S., Thomas, D., and Vandenberg, J.

Subjects

GALAXIES, REDSHIFT, ASTROPHYSICS, METAPHYSICAL cosmology, ASTRONOMY

Abstract

We present the largest, most homogeneous catalogue of merging galaxies in the nearby Universe obtained through the Galaxy Zoo project – an interface on the World Wide Web enabling large-scale morphological classification of galaxies through visual inspection of images from the Sloan Digital Sky Survey (SDSS). The method converts a set of visually inspected classifications for each galaxy into a single parameter (the ‘weighted-merger-vote fraction,’ fm) which describes our confidence that the system is part of an ongoing merger. We describe how fm is used to create a catalogue of 3003 visually selected pairs of merging galaxies from the SDSS in the redshift range . We use our merger sample and values of fm applied to the SDSS Main Galaxy Spectral sample to estimate that the fraction of volume-limited major mergers in the nearby Universe is where is a correction factor for spectroscopic incompleteness. Having visually classified the morphologies of the constituent galaxies in our mergers, we find that the spiral-to-elliptical ratio of galaxies in mergers is higher by a factor of ∼2 relative to the global population. In a companion paper, we examine the internal properties of these merging galaxies and conclude that this high spiral-to-elliptical ratio in mergers is due to a longer time-scale over which mergers with spirals are detectable compared to mergers with ellipticals. [ABSTRACT FROM AUTHOR]

Published

2010

8. Hot cores: probes of high-redshift galaxies?

Author

Lintott, C. J., Viti, S., Williams, D. A., Rawlings, J. M. C., and Ferreras, I.

Subjects

*REDSHIFT, *STAR formation, *MILKY Way, *METALS, *GALAXIES, *MOLECULES

Abstract

The very high rates of second generation star formation detected and inferred in high-redshift objects should be accompanied by intense millimetre-wave emission from hot core molecules. We calculate the molecular abundances likely to arise in hot cores associated with massive star formation at high redshift, using several different models of metallicity in the early Universe. If the number of hot cores exceeds that in the Milky Way Galaxy by a factor of at least 1000, then a wide range of molecules in high-redshift hot cores should have detectable emission. It should be possible to distinguish between different models for the production of metals and hence hot core molecules should be useful probes of star formation at high redshift. [ABSTRACT FROM AUTHOR]

Published

2005

9. THE MILKY WAY PROJECT: WHAT ARE YELLOWBALLS?

Author

Kerton, C. R., Wolf-Chase, G., Arvidsson, K., Lintott, C. J., and Simpson, R. J.

Subjects

STARS, INFRARED sources, COLOR, LUMINOSITY, GALAXIES

Abstract

Yellowballs are a collection of approximately 900 compact, infrared sources identified and named by volunteers participating in the Milky Way Project (MWP), a citizen science project that uses GLIMPSE/MIPSGAL images from Spitzer to explore topics related to Galactic star formation. In this paper, through a combination of catalog cross-matching and infrared color analysis, we show that yellowballs are a mix of compact star-forming regions, including ultra-compact and compact H II regions, as well as analogous regions for less massive B-type stars. The resulting MWP yellowball catalog provides a useful complement to the Red MSX Source survey. It similarly highlights regions of massive star formation, but the selection of objects purely on the basis of their infrared morphology and color in Spitzer images identifies a signature of compact star-forming regions shared across a broad range of luminosities and, by inference, masses. We discuss the origin of their striking mid-infrared appearance and suggest that future studies of the yellowball sample will improve our understanding of how massive and intermediate-mass star-forming regions transition from compact to more extended bubble-like structures. [ABSTRACT FROM AUTHOR]

Published

2015

10. Advancing machine learning in astrophysics

Author

Walmsley, M and Lintott, C

Subjects

astronomy, machine learning, galaxies, deep learning, computer vision

Abstract

This thesis explores four projects applying supervised deep learning to help answer astrophysical questions. I first consider faint tidal features. Tidal features are a long-lasting signature of galaxy mergers, making them useful for measuring merger rates. However, current automated methods struggle to detect faint tidal features in complex galaxies. I use convolutional neural networks to identify galaxies with tidal features in the CFHTLS- Wide Survey, improving on previous methods applied to the same dataset. I show that my networks can identify which pixels are associated with tidal features, potentially enabling researchers to not only identify but also characterise tidal features. I then turn to Galaxy Zoo, a citizen science project measuring galaxy morphology. Galaxy Zoo is being gradually outpaced by the increasing scale of new surveys. Au- tomated classifiers can be trained using volunteer responses; however, such classifiers are often unable to consider uncertainty in either volunteer responses or predictions, leading to wasted volunteer effort and overconfident classifications. I introduce a probabilistic approach that allows classifiers to flexibly express uncertainty. I use this probabilistic approach to build a machine learning system that ‘asks’ volunteers to label the galaxies it could best learn from. I relaunch Galaxy Zoo with images from the Dark Energy Camera Legacy Survey and run my system live, collecting 1.8 million volunteer responses. My final models are around 99% accurate on every question for galaxies with confident volunteer answers and are otherwise correctly uncertain. Next, I help the Canadian Hydrogen Intensity Mapping Experiment (CHIME) detect fast radio bursts. CHIME only attempts to detect FRB above a signal-to- noise threshold of σ = 8.5, in part for lack of expert time to review candidates. I created and launched a citizen science project to classify the 7.8 ≤ σ < 8.5 signal-to- noise candidates detected by CHIME each week. Candidates found by this project may be the most distant fast radio bursts ever detected, which I hope will serve as useful cosmological probes of the intergalactic medium. Finally, I show that neural network emulation can efficiently recover posteriors of galaxy parameters from photometry. Galaxy SED simulators are too slow to use MCMC inference on large samples. I train a neural network to emulate an SED simulator, providing both faster likelihood evaluations and known gradients. These gradients can then be used for efficient Hamiltonian Monte Carlo inference. Together, these projects show how deep learning can help astronomers make ef- fective use of limited and uncertain data.

Published

2021