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9,135 results on '"GALAXIES"'

3. THE BERT AND PEGGY DUPONT LECTURE: SCIENCE AND CULTURE FROM THE HUBBLE SPACE TELESCOPE.

Author

Margon B

Subjects
Galaxies, Humans, Meteoroids, Popular Culture, Solar System, Astronomy, Culture, Research
Abstract

The Hubble Space Telescope has been in Earth orbit for almost 30 years, returning an amazing variety of scientific discoveries. It can be pointed via ground command to the entire panoply of astronomical objects, from nearby targets in our solar system to the most distant objects in the known universe. While these wonderful scientific results were expected by the project's founders, what have been more surprising are the cultural aspects of the program. Hubble has been embraced by the general public to an extent unprecedented for complex scientific facilities. Not only are its images widely known for their beauty, but the project itself has repeatedly entered the popular lexicon as an example of a technological pinnacle. We present examples of the numerous scientific successes, as well as popular culture memes related to Hubble. Finally, it is also important to ponder the broader question of why we conduct astronomical research., Competing Interests: Potential Conflicts of Interest: None disclosed.

Published
2019

5. Cosmology with cosmic shear observations: a review.

Author

Kilbinger M

Subjects
Forecasting, Galaxies, Gravitation, Models, Theoretical, Optical Phenomena, Astronomy methods
Abstract

Cosmic shear is the distortion of images of distant galaxies due to weak gravitational lensing by the large-scale structure in the Universe. Such images are coherently deformed by the tidal field of matter inhomogeneities along the line of sight. By measuring galaxy shape correlations, we can study the properties and evolution of structure on large scales as well as the geometry of the Universe. Thus, cosmic shear has become a powerful probe into the nature of dark matter and the origin of the current accelerated expansion of the Universe. Over the last years, cosmic shear has evolved into a reliable and robust cosmological probe, providing measurements of the expansion history of the Universe and the growth of its structure. We review here the principles of weak gravitational lensing and show how cosmic shear is interpreted in a cosmological context. Then we give an overview of weak-lensing measurements, and present the main observational cosmic-shear results since it was discovered 15 years ago, as well as the implications for cosmology. We then conclude with an outlook on the various future surveys and missions, for which cosmic shear is one of the main science drivers, and discuss promising new weak cosmological lensing techniques for future observations.

Published
2015
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8. A complex multi-notch astronomical filter to suppress the bright infrared sky.

Author

Bland-Hawthorn J, Ellis SC, Leon-Saval SG, Haynes R, Roth MM, Löhmannsröben HG, Horton AJ, Cuby JG, Birks TA, Lawrence JS, Gillingham P, Ryder SD, and Trinh C

Subjects
Astronomical Phenomena, Astronomy instrumentation, Extraterrestrial Environment, Galaxies, Infrared Rays, Photons, Spectrum Analysis instrumentation, Telescopes, Astronomy methods, Optical Devices, Spectrum Analysis methods
Abstract

A long-standing and profound problem in astronomy is the difficulty in obtaining deep near-infrared observations due to the extreme brightness and variability of the night sky at these wavelengths. A solution to this problem is crucial if we are to obtain the deepest possible observations of the early Universe, as redshifted starlight from distant galaxies appears at these wavelengths. The atmospheric emission between 1,000 and 1,800 nm arises almost entirely from a forest of extremely bright, very narrow hydroxyl emission lines that varies on timescales of minutes. The astronomical community has long envisaged the prospect of selectively removing these lines, while retaining high throughput between them. Here we demonstrate such a filter for the first time, presenting results from the first on-sky tests. Its use on current 8 m telescopes and future 30 m telescopes will open up many new research avenues in the years to come.

Published
2011
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9. Expanding wave solutions of the Einstein equations that induce an anomalous acceleration into the Standard Model of Cosmology.

Author

Temple B and Smoller J

Subjects
Astronomy statistics & numerical data, Gravitation, Nonlinear Dynamics, Algorithms, Astronomy methods, Galaxies, Models, Statistical
Abstract

We derive a system of three coupled equations that implicitly defines a continuous one-parameter family of expanding wave solutions of the Einstein equations, such that the Friedmann universe associated with the pure radiation phase of the Standard Model of Cosmology is embedded as a single point in this family. By approximating solutions near the center to leading order in the Hubble length, the family reduces to an explicit one-parameter family of expanding spacetimes, given in closed form, that represents a perturbation of the Standard Model. By introducing a comoving coordinate system, we calculate the correction to the Hubble constant as well as the exact leading order quadratic correction to the redshift vs. luminosity relation for an observer at the center. The correction to redshift vs. luminosity entails an adjustable free parameter that introduces an anomalous acceleration. We conclude (by continuity) that corrections to the redshift vs. luminosity relation observed after the radiation phase of the Big Bang can be accounted for, at the leading order quadratic level, by adjustment of this free parameter. The next order correction is then a prediction. Since nonlinearities alone could actuate dissipation and decay in the conservation laws associated with the highly nonlinear radiation phase and since noninteracting expanding waves represent possible time-asymptotic wave patterns that could result, we propose to further investigate the possibility that these corrections to the Standard Model might be the source of the anomalous acceleration of the galaxies, an explanation not requiring the cosmological constant or dark energy.

Published
2009
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12. An Empirical Consistent Redshift Bias: A Possible Direct Observation of Zwicky's TL Theory.

Author

Shamir, Lior

Subjects
LARGE scale structure (Astronomy), MILKY Way, ROTATION of galaxies, GALAXY formation, ASTRONOMY
Abstract

Recent advancements have shown tensions between observations and our current understanding of the Universe. Such observations may include the H 0 tension and massive galaxies at high redshift that are older than traditional galaxy formation models have predict. Since these observations are based on redshift as the primary distance indicator, a bias in the redshift may explain these tensions. While redshift follows an established model, when applied to astronomy it is based on the assumption that the rotational velocity of the Milky Way galaxy relative to the observed galaxies has a negligible effect on redshift. But given the mysterious nature of the physics of galaxy rotation, that assumption needed to be tested. The test was done by comparing the redshift of galaxies rotating in the same direction relative to the Milky Way to the redshift of galaxies rotating in the opposite direction relative to the Milky Way. The results show that the mean redshift of galaxies that rotate in the same direction relative to the Milky Way is higher than the mean redshift of galaxies that rotate in the opposite direction. Additionally, the redshift difference becomes larger as the redshift gets higher. The consistency of the analysis was verified by comparing data collected by three different telescopes, annotated using four different methods, released by three different research teams, and covering both the northern and southern ends of the galactic pole. All the datasets are in excellent agreement with each other, showing consistency in the observed redshift bias. Given the "reproducibility crisis" in science, all the datasets used in this study are publicly available, and the results can be easily reproduced. This observation could be the first direct empirical reproducible observation for the Zwicky's "tired-light" model. [ABSTRACT FROM AUTHOR]

Published
2024
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13. The Host Galaxy Fluxes of Active Galaxy Nuclei Are Generally Overestimated by the Flux Variation Gradient Method.

Author

Cai, Minxuan, Wan, Zhen, Cai, Zhenyi, Fan, Lulu, and Wang, Junxian

Subjects
*SEYFERT galaxies, *ACTIVE galaxies, *GALAXIES, *ASTRONOMY, *QUASARS, *COLOR
Abstract

In terms of the variable nature of normal active galaxy nuclei (AGN) and luminous quasars, a so-called flux variation gradient (FVG) method has been widely utilized to estimate the underlying non-variable host galaxy fluxes. The FVG method assumes an invariable AGN color, but this assumption has been questioned by the intrinsic color variation of quasars and local Seyfert galaxies. Here, using an up-to-date thermal fluctuation model to simulate multi-wavelength AGN variability, we theoretically demonstrate that the FVG method generally overestimates the host galaxy flux; that is, it is more significant for brighter AGN/quasars. Furthermore, we observationally confirm that the FVG method indeed overestimates the host galaxy flux by comparing it to that estimated through other independent methods. We thus caution that applying the FVG method should be performed carefully in the era of time-domain astronomy. [ABSTRACT FROM AUTHOR]

Published
2024
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14. Ciel&espace: CALENDRIER 2025.

Subjects
*STAR observations, *SOLAR eclipses, *ASTRONOMY, *GALAXIES, *MARS (Planet), *LUNAR eclipses
Abstract

The document "Sky & Space: CALENDAR 2025" presents information on various upcoming astronomical events in 2025. It highlights observations such as the European probe Mars Express capturing images of Argyre Planitia on Mars, planetary conjunctions, solar and lunar eclipses, as well as observations of stars and galaxies. Details on asteroids, nebulae, and celestial phenomena are also included. The document also provides information on night observation stations and introductory astronomy courses. [Extracted from the article]

Published
2024

15. Spectral energy distribution modelling of X-ray selected AGNs and their host galaxies

Author

Marshall, Adam, Banerji, Manda, Maiolino, Roberto, and Auger-Williams, Matthew

Subjects
Astronomy, Astrophysics, Galaxies, AGN
Abstract

The nature of the relation between active galactic nuclei (AGN), and their host galaxies have been observed in detail throughout the Universe. Such work has found an intrinsic link between central supermassive black hole (SMBH) masses, and host galaxy properties such as the velocity dispersion of stars, and bulge mass. However, the difference in scale between SMBH and their host galaxies has led to debate on how this relation might form, and develop over time. In order to aid in understanding the relation between AGN and their host galaxies, the work throughout this thesis has therefore focused on the development and implementation of a new SED fitting code, using an up-to-date AGN SED to accurately infer both AGN and host galaxy properties. To this end, we explore the intricacies involved in producing useful property inferences using a Bayesian MCMC fitting method, whilst working to avoid common issues such as bimodality and lack of convergence. We then perform SED fitting using our methods to 711 luminous X-ray AGN at 0.7 < z < 4.5 using 10-bands of optical and infra-red photometric data for objects within XMMSERVS. Using these fits, we study the relation between AGN X-ray luminosity and host galaxy stellar mass, along with our ability to predict emission line strength and morphology from photometry alone. In order to further understand the intricacies of SED fitting, we also provide a case study into the effect of AGN SED choice on host galaxy and AGN property inferences, by comparing our AGN SED to another commonly used template. In this work, we show that it is important to consider host galaxy contamination when trying to produce a pure AGN template, and the effect that this contamination can have on AGN and host galaxy property inferences. We also find that the use of lower resolution SEDs can lead to repercussions on property inferences such as host galaxy stellar mass, which may provide incorrect assumptions on the relation between AGN and their host galaxies.

Published
2023
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16. A Critical Examination of the Standard Cosmological Model: Toward a Modified Framework for Explaining Cosmic Structure Formation and Evolution

Author

Robert Nyakundi Nyagisera, Dismas Wamalwa, Bernard Rapando, Celline Awino, and Maxwell Mageto

Subjects
modified redshift, light intensity, number density, accelerated expansion, galaxies, structure formation, Astronomy, QB1-991
Abstract

This paper explores the fundamental cosmological principle, with a specific focus on the homogeneity and isotropy assumptions inherent in the Friedmann model that underpins the standard model. We propose a modified redshift model that is based on the spatial distribution of luminous matter, examining three key astronomical quantities: light intensity, number density, and the redshift of galaxies. Our analysis suggests that the model can account for cosmic accelerated expansion without the need for dark energy in the equations. Both simulations and analytical solutions reveal a unique pattern in the formation and evolution of cosmic structures, particularly in galaxy formation. This pattern shows a significant burst of activity between redshifts 0 < z < 0.4, which then progresses rapidly until approximately z ≈ 0.9, indicating that the majority of cosmic structures were formed during this period. Subsequently, the process slows down considerably, reaching a nearly constant rate until around z ≈ 1.6, after which a gradual decline begins. We also observe a distinctive redshift transition around z ≈ 0.9 before the onset of dark-matter-induced accelerated expansion. This transition is directly related to the matter density and is dependent on the geometry of the universe. The model’s ability to explain cosmic acceleration without requiring fine tuning of the cosmological constant highlights its novelty, providing a fresh perspective on the dynamic evolution of the universe.

Published
2024
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17. Galaxies make a zigzag lens

Subjects
Galaxies, Astronomy, Force and energy
Abstract

News Astronomy Galaxies make a zigzag lens Light from a distant quasar is being deflected by not one but two massive galaxies, giving us a unique opportunity to probe the [...]

Published
2024

18. Galaxies make a zigzag lens

Subjects
Galaxies, Astronomy, Force and energy
Abstract

News Astronomy Galaxies make a zigzag lens Light from a distant quasar is being deflected by not one but two massive galaxies, giving us a unique opportunity to probe the [...]

Published
2024

19. The Milky Way represents an outlier among similar galaxies

Subjects
Dark matter (Astronomy), Galaxies, Aerospace and defense industries, Astronomy, High technology industry, Telecommunications industry
Abstract

Stanford CA (SPX) Nov 22, 2024 For decades, scientists have used the Milky Way as a model for understanding how galaxies form. But a trio of new studies raises questions [...]

Published
2024

20. Hunting for the Beacons of the Universe.

Subjects
CEPHEIDS, STARS, ASTRONOMY, GALAXIES, UNIVERSE
Abstract

The article focuses on the significance of Cepheid variable stars in astronomy and their role in measuring cosmic distances. It discusses how the period-luminosity relationship discovered by Henrietta Leavitt laid the foundation for determining distances to distant stars and galaxies, thus contributing to our understanding of the universe's structure and expansion.

Published
2024

21. A two-step strategy to identify episodic sources of gravitational waves and high-energy neutrinos in starburst galaxies

Author

M. L. Allen, P. L. Biermann, L. I. Caramete, A. Chieffi, R. Chini, D. Frekers, L. Á. Gergely, B. Harms, I. Jaroschewski, P. S. Joshi, P. P. Kronberg, E. Kun, A. Meli, E.-S. Seo, and T. Stanev

Subjects
neutrinos, starburst, galaxies, black hole mergers, gravitational waves, particle acceleration, Astronomy, QB1-991, Geophysics. Cosmic physics, QC801-809
Abstract

Supermassive black hole (BH) mergers with spin-flips accelerate energetic particles through their relativistic precessing jets, producing high-energy neutrinos and finally gravitational waves (GWs). In star formation, massive stars form in pairs, triplets, and quadruplets, allowing second-generation mergers of the remnants with discrepant spin directions. The GW data support such a scenario. Earlier, we suggested that stellar mass BH mergers (visible in M82) with an associated spin-flip analogously allow the acceleration of energetic particles, with ensuing high-energy neutrinos and high-energy photons, and finally produce GWs. At cosmic distances, only the GWs and the neutrinos remain detectable. In this study, we generalize the argument to starburst and normal galaxies throughout their cosmic evolution and show that these galaxies may dominate over active galactic nuclei (AGN) in the flux of ultra-high-energy particles observed at Earth. All these sources contribute to the cosmic neutrino background, as well as the GW background (they detected lower frequencies). We outline a search strategy to find such episodic sources, which requires including both luminosity and flux density.

Published
2024
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22. Galaxy-Classification Activity for All Ages

Author

Cooksey, Kathy L, Metevier, Anne J, Rubin, Kate HR, Choi, Philip I, and Raschke, Lynne

Subjects
activity design, astronomy, classification, facilitation, galaxies
Abstract

Classification is a general tool of science; it is used to sort and categorize biological organisms, chemical elements, astronomical objects, and many other things. In scientific classification, taxonomy often reflects shared physical properties that, in turn, may indicate shared origins and/or evolution. A “hands-on” galaxy-classification activity developed and implemented by Professional Development Program (PDP) participants, for a high-school summer STEM enrichment program, has been adopted for various age groups and venues, from young (K–3) to college students. We detail the basic tools required, outline the general activity, and describe the modifications to the activity based on learners’ ages and learning objectives. We describe the facilitation strategies learned through PDP training and used when implementing the activity, including prompts to motivate the students. We also discuss how we connected the classification process to astronomy and science more broadly during the concluding remarks.

Published
2022

23. Interacting Galaxies Captured by Webb in Stunning Detail

Subjects
Telescope, Galaxies, Optical instruments, Aerospace and defense industries, Astronomy, High technology industry, Telecommunications industry
Abstract

Paris, France (SPX) Jul 15, 2024 To mark the second anniversary of the NASA/ESA/CSA James Webb Space Telescope's scientific operations, a captivating image of two interacting galaxies known as Arp [...]

Published
2024

24. Using deep learning to explore ultra-large scale astronomical datasets

Author

Smith, Michael J.

Subjects
Neural Networks, Astronomy, Deep Learning, Galaxies
Abstract

In every field that deep learning has infiltrated we have seen a reduction in the use of specialist knowledge, to be replaced with knowledge automatically derived from data. We have already seen this process play out in many 'applied deep learning' fields such as computer Go, protein folding, natural language processing, and computer vision. This thesis argues that astronomy is no different to these applied deep learning fields. To this end, this thesis' introduction serves as a historical background on astronomy's 'three waves' of increasingly automated connectionism: initial work on multilayerperceptrons within astronomy required manually selected emergent properties as input; the second wave coincided with the dissemination of convolutional neural networks and recurrent neural networks, models where the multilayer perceptron's manually selected inputs are replaced with raw data ingestion; and in the current third wave we are seeing the removal of human supervision altogether with deep learning methods inferring labels and knowledge directly from the data. §2, §3, and §4 of this thesis explore these waves through application. In §2 I show that a convolutional/recurrent encoder/decoder network is capable of emulating a complicated semi-manual galaxy processing pipeline. I find that this 'Pix2Prof' neural network can satisfactorily carry out this task over 100x faster than the method it emulates. §3 and §4 explore the application of deep generative models to astronomical simulation. §3 uses a generative adversarial network to generate mock deep field surveys, and finds it capable of generating mock images that are statistically indistinguishable from the real thing. Likewise, §4 demonstrates that a Diffusion model is capable of generating galaxy images that are both qualitatively and quantitatively indistinguishable from the training set. The main benefit of these deep learning based simulations is that they do not rely on a possibly flawed (or incomplete) physical knowledge of their subjects and observation processes. Also, once trained, they are capable of rapidly generating a very large amount of mock data. §5 looks to the future and predicts that we will soon enter a fourth wave of astronomical connectionism. If astronomy follows in the footsteps of other applied deep learning fields we will see the removal of expertly crafted deep learning models, to be replaced with finetuned versions of an all-encompassing 'foundation' model. As part of this fourth wave I argue for a symbiosis between astronomy and connectionism. This symbiosis is predicated on astronomy's relative data wealth, and contemporary deep learning's enormous data appetite; many ultra-large datasets in machine learning are proprietary or of poor quality, and so astronomy as a whole could develop and provide a high quality multimodal public dataset. In turn, this dataset could be used to train an astronomical foundation model that can be used for state-of-the-art downstream tasks. Due to the foundation models' hunger for data and compute, a single astronomical research group could not bring about such a model alone. Therefore, I conclude that astronomy as a whole has slim chance of keeping up with a research pace set by the Big Tech goliaths-that is, unless we follow the examples of EleutherAI and HuggingFace and pool our resources in a grassroots open source fashion.

Published
2022
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25. Exploring the environments and host galaxies of SGRB progenitors in the era of multi-messenger astronomy

Author

Mandhai, Soheb

Subjects
astronomy, host galaxies, Space Science, compact binaries, cosmos, gravitational waves, SGRBs, short gamma-ray bursts, neutron stars, GW170817, giant flares, soft gamma-ray repeaters, black holes, multi-messenger astrophysics, GW detectors, binaries, Cosmological simulation, trace galaxy dynamics, galaxies, redshifts, electromagnetic counterparts, Local Universe, kilonovae, Neutron Star mergers, universe, astrophysics, Gravitational wave sources, Thesis
Abstract

The in-spiral of compact binary systems consisting of a neutron star paired with either a black-hole or another neutron star produces distortions in space-time known as gravitational waves (GW). In the presence of sufficient ejecta, electromagnetic phenomena such as short-duration gamma-ray bursts (SGRBs) or kilonovae can be produced. In this thesis, I explore the environments, redshifts, and host galaxy demographics of these compact binaries. Using my Redshift Electromagnetic Localisation and Deduction Algorithm (zELDA), I seed BPASS and COSMIC evolved binaries into hydro-dynamical galaxies from the EAGLE simulation. I then trace the orbits of the binaries until they merge. I apply a selection criterion to a simulated SGRB sample to gauge the consistency with observations. I find agreements with the observed redshifts, host galaxy demographics, and offsets. I predict 16 -40% of SGRB events would appear "host-less", i.e. sources that merge with high impact parameters or have faint hosts (H > 26). Given the close proximity of GW170817 at ~ 40Mpc, I consider the constraints on a local population of low-luminosity SGRBs. I gauge the likelihood of SGRBs with host galaxies within < 200Mpc. I get an all-sky rate of < 6 yr⁻¹ using well-localised bursts (with precisions of ~ arcmin - arcsec) from 'Swift'/BAT, corresponding to ~ 8% of 'Swift' SGRBs. By cross-correlating poorly localised bursts from the CGRO/BATSE and Fermi/GBM with galaxies within < 100Mpc, I find a weaker constraint of £ 12 yr⁻¹ for the all-sky rate. I conduct a separate search to constrain the rate of nearby (d < 11Mpc) giant flares from Soft Gamma-Ray Repeaters (SGRs) and place an upper limit of < 3 yr⁻¹. I conclude this thesis by commenting on the implications of our findings on future studies.

Published
2022
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26. The High-Energy X-ray Probe (HEX-P): the circum-nuclear environment of growing supermassive black holes

Author

P. G. Boorman, N. Torres-Albà, A. Annuar, S. Marchesi, R. W. Pfeifle, D. Stern, F. Civano, M. Baloković, J. Buchner, C. Ricci, D. M. Alexander, W. N. Brandt, M. Brightman, C. T. Chen, S. Creech, P. Gandhi, J. A. García, F. Harrison, R. Hickox, E. Kammoun, S. LaMassa, G. Lanzuisi, L. Marcotulli, K. Madsen, G. Matt, G. Matzeu, E. Nardini, J. M. Piotrowska, A. Pizzetti, S. Puccetti, D. Sicilian, R. Silver, D. J. Walton, D. R. Wilkins, X. Zhao, and The HEX-P Collaboration

Subjects
X-ray, active galactic nuclei, obscuration, black hole, galaxies, Compton-thick, Astronomy, QB1-991, Geophysics. Cosmic physics, QC801-809
Abstract

Ever since the discovery of the first active galactic nuclei (AGN), substantial observational and theoretical effort has been invested into understanding how massive black holes have evolved across cosmic time. Circum-nuclear obscuration is now established as a crucial component, with almost every AGN observed known to display signatures of some level of obscuration in their X-ray spectra. However, despite more than six decades of effort, substantial open questions remain: how does the accretion power impact the structure of the circum-nuclear obscurer? What are the dynamical properties of the obscurer? Can dense circum-nuclear obscuration exist around intrinsically weak AGN? How many intermediate mass black holes occupy the centers of dwarf galaxies? In this paper, we showcase a number of next-generation prospects attainable with the High-Energy X-ray Probe (HEX-P1) to contribute toward solving these questions in the 2030s. The uniquely broad (0.2–80 keV) and strictly simultaneous X-ray passband of HEX-P makes it ideally suited for studying the temporal co-evolution between the central engine and circum-nuclear obscurer. Improved sensitivities and reduced background will enable the development of spectroscopic models complemented by current and future multi-wavelength observations. We show that the angular resolution of HEX-P both below and above 10 keV will enable the discovery and confirmation of accreting massive black holes at both low accretion power and low black hole masses even when concealed by thick obscuration. In combination with other next-generation observations of the dusty hearts of nearby galaxies, HEX-P will be pivotal in paving the way toward a complete picture of black hole growth and galaxy co-evolution.

Published
2024
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27. Retrograde infall of the intergalactic gas onto S-galaxy and activity of galactic nuclei

Author

Khrapov Sergey S. and Khoperskov Alexander V.

Subjects
galaxies, gas accretion, counterrotation, numerical simulation, Astronomy, QB1-991
Abstract

We present the results of numerical simulations focused on the accretion of intergalactic gas onto a gas-rich S-type disc galaxy. Our investigation explores the conditions favouring the emergence of counterrotating stellar and gaseous components within the galaxy, leading to the inflow of gas towards the central kiloparsec of the galaxy. Notably, we find that the most substantial reservoir of gas, serving as fuel for galactic nucleus activity, resides within the central region during the retrograde infall of gas at an incident angle of approximately 20°2{0}^{^\circ } relative to the galactic plane. Departures from this angle significantly diminish the gas flow rate towards the galactic centre. Conversely, the prograde infall of intergalactic gas makes a marginal contribution to the gas content in the central region and cannot supply fuel to the active galactic nucleus. An intriguing characteristic of the observed retrograde impact is the emergence of a rotating polar ring at the galaxy’s periphery, primarily originating from intergalactic gas.

Published
2024
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28. SETI SEARCHES FOR ALIEN LIFE IN OVER 1,000 GALAXIES USING UNEXPLORED RADIO FREQUENCIES: Although no aliens were found, the results have helped constrain expectations of possible alien transmitter power

Author

Cooper, Keith

Subjects
Life on other planets, Galaxies, Astronomy
Abstract

A search of more than 1,300 galaxies for extraterrestrial signals has helped constrain expectations as to how many communicating technological civilisations may exist beyond Earth. Conducted with the Murchison Widefield [...]

Published
2024

30. New Strong Constraints on the Central Behaviour of Spherical Galactic Models

Author

Marco Roncadelli and Giorgio Galanti

Subjects
galaxies, general, galaxy clusters, cosmology, Astronomy, QB1-991
Abstract

First of all, we show that any spherically symmetric galactic model with integrated mass profile M(r)→0 as r→0 is physically correct close to the centre only provided that the circular velocity vc(r)→0 and the gravitational field g(r)→0 as r→0. Next, we apply this statement to a broad class of five-parameter spherical galactic models, including most of those used in astrophysics and cosmology. Specifically, we show that the Jaffe and Hernquist models can be trusted only for r≳0.2Re (Re being the effective radius), while the Navarro–Frank–White (NFW) model cannot describe galaxies in the central region of regular clusters. We also briefly discuss the relevance of our result for the NFW profile of pure dark matter halos. However, we are unable to tell at which central distance the NFW model breaks down in either case, and this is a challenge for future investigations.

Published
2023
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31. SS 433: Flares and L2 Overflow Spirals

Author

Michael Bowler

Subjects
X-rays, binaries, ULX, stars, SS 433, galaxies, Astronomy, QB1-991
Abstract

Flaring in the SS 433 microquasar is dominated by outbursts from material at distances from the centre of mass of the binary system comparable to the separation of the two components. This note completes a demonstration that ejected plasma leaves the system in the region of the L2 point, there overflowing the outer Roche lobe and giving rise to a spiral structure as it leaves the system as part of the local environment. It also provides a new measure of the mass ratio of the binary.

Published
2024
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32. Correlations between IR Luminosity, Star Formation Rate, and CO Luminosity in the Local Universe

Author

Matteo Bonato, Ivano Baronchelli, Viviana Casasola, Gianfranco De Zotti, Leonardo Trobbiani, Erlis Ruli, Vidhi Tailor, and Simone Bianchi

Subjects
infrared, galaxies, star formation, statistics, Astronomy, QB1-991
Abstract

We exploit the DustPedia sample of galaxies within approximately 40 Mpc, selecting 388 sources, to investigate the correlations between IR luminosity (LIR), the star formation rate (SFR), and the CO(1-0) luminosity (LCO) down to much lower luminosities than reached by previous analyses. We find a sub-linear dependence of the SFR on LIR. Below log(LIR/L⊙)≃10 or SFR≃1M⊙yr−1, the SFR/LIR ratio substantially exceeds the standard ratio for dust-enshrouded star formation, and the difference increases with decreasing LIR values. This implies that the effect of unobscured star formation overcomes that of dust heating by old stars, at variance with results based on the Planck ERCSC galaxy sample. We also find that the relations between the LCO and LIR or the SFR are consistent with those obtained at much higher luminosities.

Published
2024
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33. A Supermassive Binary Black Hole Candidate in Mrk 501

Author

Gustavo Magallanes-Guijón and Sergio Mendoza

Subjects
galaxies, quasars, individual, Mrk 501—galaxies, supermassive black holes, Astronomy, QB1-991
Abstract

Using multifrequency observations, from radio to γ-rays of the blazar Mrk 501, we constructed their corresponding light curves and built periodograms using RobPer and Lomb–Scargle algorithms. Long-term variability was also studied using the power density spectrum and the detrended function analysis. Using the software VARTOOLS Version 1.40, we also computed the analysis of variance, box-least squares and discrete fourier transform. The result of these techniques showed an achromatic periodicity ≲229d. This, combined with the result of pink-color noise in the spectra, led us to propose that the periodicity was produced via a secondary eclipsing supermassive binary black hole orbiting the primary one locked inside the central engine of Mrk 501. We built a relativistic eclipsing model of this phenomenon using Jacobi elliptical functions, finding a periodic relativistic eclipse occurring every ∼224d in all the studied wavebands. This implies that the frequency of the emitted gravitational waves falls slightly above 0.1 mHz, well within the operational range of the upcoming LISA space-based interferometer, and as such, these gravitational waves must be considered as a prime science target for future LISA observations.

Published
2024
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34. The bright end of the galaxy luminosity function at z ≃ 7 from the VISTA VIDEO survey.

Author

Varadaraj, R G, Bowler, R A A, Jarvis, M J, Adams, N J, and Häußler, B

Subjects
*STELLAR luminosity function, *BROWN dwarf stars, *GALAXIES, *LUMINOSITY, *STELLAR mass, *GALACTIC evolution, *ASTRONOMY
Abstract

We have conducted a search for z  ≃ 7 Lyman-break galaxies over 8.2 deg2 of near-infrared imaging from the Visible and Infrared Survey Telescope for Astronomy (VISTA) Deep Extragalactic Observations (VIDEO) survey in the XMM–Newton -Large Scale Structure (XMM-LSS) and the Extended Chandra Deep Field -South (ECDF-S) fields. Candidate galaxies were selected from a full photometric redshift analysis down to a Y + J depth of 25.3 (5σ), utilizing deep auxiliary optical and Spitzer /Infrared Array Camera (IRAC) data to remove brown dwarf and red interloper galaxy contaminants. Our final sample consists of 28 candidate galaxies at 6.5 ≤ z ≤ 7.5 with −23.5 ≤ M UV ≤ −21.6. We derive stellar masses of 9.1 ≤ log10(M ⋆/M⊙) ≤ 10.9 for the sample, suggesting that these candidates represent some of the most massive galaxies known at this epoch. We measure the rest-frame ultraviolet (UV) luminosity function (LF) at z ≃ 7, confirming previous findings of a gradual decline in number density at the bright end (M UV < −22) that is well described by a double power law (DPL). We show that quasar contamination in this magnitude range is expected to be minimal, in contrast to conclusions from recent pure-parallel Hubble studies. Our results are up to a factor of 10 lower than previous determinations from optical-only ground-based studies at M UV ≲ −23. We find that the inclusion of YJHK s photometry is vital for removing brown dwarf contaminants, and z ≃ 7 samples based on red optical data alone could be highly contaminated (≳50 per cent). In comparison with other robust z > 5 samples, our results further support little evolution in the very bright end of the rest-frame UV LF from z  = 5–10, potentially signalling a lack of mass quenching and/or dust obscuration in the most massive galaxies in the first Gyr. [ABSTRACT FROM AUTHOR]

Published
2023
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35. The Detailed Environments around Distant Quasars and Advanced Techniques in Point Spread Function Reconstruction

Author

Sabhlok, Sanchit

Subjects
Astrophysics, Astronomy, CGM, Galaxies, LLR, PSF Reconstruction, Quasars, Radio-loud
Abstract

Galaxies evolve over cosmic times in tandem with their larger environments (O(10 - 100 kpc)), which are influenced by galactic processes such as star formation and outbursts from an accreting supermassive black hole, also known as an Active Galactic Nucleus (AGN). The circumgalactic medium (CGM) is a reservoir of gas that surrounds all galaxies and is the recipient of galactic scale outflows, driven by either star formation or AGN activity, but also supplies the gas needed by the host galaxy to sustain star formation. The larger environment also impacts the CGM brightness, kinematics and metallicity, due to companion galaxy subhalos and mergers, thus offering a unique opportunity to observe the interplay between galactic and environmental processes. Our multi-wavelength dataset of seven distant (z~2) radio-loud quasars allows us to investigate these interactions. Using data from W. M. Keck Observatory and archival data from the Very Large Array and ALMA radio facilities, and Hubble and Spitzer Space Telescopes, we observe outflows driven by the AGN, spatially resolved host galaxy emissions, CGM Ly-alpha, He II, and C IV emission and the influence of companion galaxies. We find evidence for a two component CGM model, where the inner CGM is directly influenced by the quasar host galaxy, whereas the outer CGM is influenced tidal interactions with companion galaxies and the turbulent motion of the gas.Adaptive Optics (AO) has enabled higher angular resolution observations from the ground. Understanding the Point Spread Function (PSF) of the telescope limits our ability to disentangle phenomena at small angular resolution. A forward modelled PSF reconstruction represents the "pinnacle" of ground-based observational astronomy, since true knowledge of the observational PSF will reduce uncertainties in photometry and astrometry for all science cases. We investigate a PSF model for the NIRC2 instrument using AO telemetry data on Keck telescope and validate its performance using on-sky data. As a special application, we also investigate the PSF of the Corner Cube Retroreflectors left on the moon by Apollo astronauts, to investigate the performance degradation of these devices over the last 50 years due to dust deposition on their surfaces.

Published
2024

36. Radial Flows and Torques in Cosmological Simulations of Milky Way Mass Galaxies

Author

Trapp, Cameron William

Subjects
Astrophysics, Astronomy, Physics, accretion, computational, galaxies, machine learning, simulation, star formation
Abstract

Observations indicate that a continuous supply of gas is needed to maintain observed star formation rates in large, disky galaxies. To fuel star formation, gas must reach the inner regions of such systems. Despite its crucial importance for galactic evolution, how/where gas joins disks is poorly constrained observationally and rarely explored in fully cosmological simulations. To investigate gas accretion onto galaxies at low redshift and how it fuels star formation in central regions, we analyze the FIRE-2 cosmological zoom-in simulations, focusing on 4 Milky Way mass galaxies (M_halo~10^12 M_solar).In Chapter 2, we present a phenomenological analysis of how gas accretes onto simulated Milky Way mass disks and transports inwards, fueling star formation. We find that at z~0, gas approaches the disk with angular momentum similar to the gaseous disk edge and average radial speeds of 10-20 km/s, piling up near the edge and settling into full rotational support. These flows are largely hidden from observations that search for inflows via large deviations from galactic rotation. Within the disk, average radial speeds slow down to a few km/s of inward motion. Radial motion of the gas in the disk is complex, dominated by spiral arm-induced oscillations and feedback effects.In Chapter 3, we present a study on the torques that drive these flows. Gas in the disk is fully rotationally supported, so must lose angular momentum to move inward. In this chapter, we characterize gravitational torques from stars, dark matter, and gas-gas interactions; magnetohydrodynamical torques from pressure gradients, non-continuum hydrodynamical terms, magnetic fields, and viscous shearing; and torques from stellar feedback.In Chapter 4, we present an analysis of how to constrain these radial flows in observations, focusing on the use of Convolutional Neural Networks (CNNs) to infer radial mass fluxes from HI 21 cm spectral data cubes. Constraining flows within the disks of galaxies is particularly difficult, with large observational uncertainties. We additionally compare the use of more traditional tilted ring modeling to infer radial mass flux rates with CNN performance and find that our networks offer similar or better accuracy with dramatically enhanced speeds.

Published
2024

37. Huge set of galaxies set to form largest known cluster

Subjects
Galaxies, Astronomy
Abstract

News Astronomy Huge set of galaxies set to form largest known cluster Alex Wilkins ONE of the largest quasars in the early universe has helped to reveal a vast “protocluster” [...]

Published
2024

38. Advancing machine learning in astrophysics

Author

Walmsley, Mike and Lintott, Christopher

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

39. Galaxy-scale signatures of screened modified gravities

Author

Naik, Aneesh, Puchwein, Ewald, Sijacki, Debora, and Davis, Anne

Subjects
Astronomy, Gravitation, Fundamental Physics, Galaxies, Dark Energy, Dark Matter
Abstract

In recent years, theories of gravity incorporating a scalar field coupled to gravity---'scalar-tensor' theories---have been subject to increased attention. In these theories, the scalar field mediates gravitational-strength 'fifth forces'. For such scalar fields to retain cosmological relevance while also evading stringent constraints from high-precision post-Newtonian tests of gravity, 'screening mechanisms' are invoked, in which the fifth force is suppressed in regions of high density or deep gravitational potential. One example of a screening mechanism is the 'chameleon' mechanism, in which the scalar has a density-dependent mass, such that the mass becomes very large in regions of high density, and the fifth force is exponentially suppressed as a consequence. While the primary effect of screening mechanisms is to mask the effects of modified gravity in the Solar System, they can nevertheless give rise to interesting astrophysical signatures elsewhere, searches for which can serve as tests of screened modified gravity. These signatures are the subject of this thesis. The Introduction of this thesis in Chapter 1 presents some historical background and scientific context, particularly in the fields of cosmology, the astrophysics of galaxies, and screened modified gravity theories. Subsequently, Chapters 2, 3, and 4 present original research regarding two galaxy-scale signatures of screened modified gravity: 'upturns' in galaxy rotation curves and asymmetries in stellar streams. If a galaxy is partially screened, it will have a 'screening radius', within which the fifth force is suppressed. Outside the screening radius, the fifth force on a test particle will be proportional to the mass enclosed in the shell between the test particle and the screening radius. Thus, the fifth force will contribute to the galaxy's rotation curve, but only outside the screening radius. At the screening radius itself, there will be an upturn in the curve. In Chapter 2, based on an article published in the Monthly Notices of the Royal Astronomical Society (Naik et al., 2018), I give the first prediction of this effect, specifically in the context of Hu-Sawicki f(R) gravity, a widely-studied example of a chameleon theory. By post-processing simulated galaxies of the Auriga Project using the f(R) gravity code MG-Gadget, I produce mock rotation curves for a range of galaxy masses and values of the key theory parameter fR0, forecasting competitive constraints on fR0. In Chapter 3, also based on an article published in the Monthly Notices (Naik et al., 2019), I turn to observational data. Analysing the high-quality rotation curves of the SPARC sample, I find that in certain f(R) parameter regimes there is a strong signal, but it is better explained with standard gravity plus a 'cored' dark matter halo profile than with modified gravity plus a theoretically-predicted 'cuspy' halo. I am thus able to place competitive constraints on f(R) gravity, with the caveat that if cored haloes can not ultimately be motivated under the standard ΛCDM cosmological paradigm, then screened modified gravity could feasibly ease the tension between observed cores and predicted cusps. In Chapter 4, I consider the observable imprints of screening on stellar streams around the Milky Way. For reasonable parameter regimes in chameleon theories, main sequence stars will be screened, and thus neither source nor couple to the fifth force. Thus, a situation can arise in which a dark matter dominated dwarf galaxy is unscreened, but the stars within it are screened. If such a galaxy were to be tidally disrupted by the Milky Way, its stars would be preferentially stripped into the trailing stellar stream rather than the leading stream. The streams would therefore be asymmetric about their progenitor. Using a restricted N-body method, I explore this effect for a variety of satellite orbits and modified gravity regimes. Taking f(R) gravity as a fiducial theory, I forecast some of the strongest constraints to date from future data releases of the Gaia satellite. This chapter is based on an article submitted to Physical Review D (Naik et al., 2020). Finally, Chapter 5 gives some concluding remarks and a discussion of future prospects in this field.

Published
2020
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40. AGN Feedback Signatures in UV Emission

Author

K. Rubinur

Subjects
galaxies, active, AGN feedback, Seyfert, galaxy merger, UV continuum, Astronomy, QB1-991
Abstract

Supermassive black holes (SMBH) are believed to influence galaxy evolution through AGN (active galactic nuclei) feedback. Galaxy mergers are key processes of galaxy formation that lead to AGN activity and star formation. The relative contribution of AGN feedback and mergers to star formation is not yet well understood. In radio-loud objects, AGN outflows are dominated by large jets. However, in radio-quiet objects, outflows are more complex and involve jet, wind, and radiation. In this review, we discuss the signatures of AGN feedback through the alignment of radio and UV emissions. Current research on AGN feedback is discussed, along with a few examples of studies such as the galaxy merger system MRK 212, the radio-quiet AGN NGC 2639, and the radio-loud system Centaurus A. Multi-frequency observations of MRK 212 indicate the presence of dual AGN, as well as feedback-induced star-forming UV clumps. The fourth episode of AGN activity was detected in radio observations of the Seyfert galaxy NGC 2639, which also showed a central cavity of 6 kpc radius in CO and UV maps. This indicates that multi-epoch jets of radio-quiet AGN can blow out cold molecular gas, which can further reduce star formation in the center of the galaxies. Recent UV observations of Cen A have revealed two sets of stellar population in the northern star-forming region, which may have two different origins. Recent studies have shown that there is evidence that both positive and negative feedback can be present in galaxies at different scales and times. High-resolution, multi-band observations of large samples of different types of AGN and their host galaxies are important for understanding the two types of AGN feedback and their effect on the host galaxies. Future instruments like INSIST and UVEX will be able to help achieve some of these goals.

Published
2024
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41. Observational Tests of Active Galactic Nuclei Feedback: An Overview of Approaches and Interpretation

Author

Chris M. Harrison and Cristina Ramos Almeida

Subjects
galaxies, active galactic nuclei, feedback, jets, outflows, Astronomy, QB1-991
Abstract

Growing supermassive black holes (Active Galactic Nuclei; AGN) release energy with the potential to alter their host galaxies and larger-scale environment; a process named “AGN feedback”. Feedback is a required component of galaxy formation models and simulations to explain the observed properties of galaxy populations. We provide a broad overview of observational approaches that are designed to establish the physical processes that couple AGN energy to the multi-phase gas, or to find evidence that AGN impact upon galaxy evolution. The orders-of-magnitude range in spatial, temporal, and temperature scales, requires a diverse set of observational studies. For example, studying individual targets in detail sheds light on coupling mechanisms; however, evidence for the long-term impact of AGN is better established within galaxy populations that are not necessarily currently active. We emphasise how modern surveys have revealed the importance of radio emission for identifying and characterising feedback mechanisms. At the achieved sensitivities, the detected radio emission can trace a range of processes, including a shocked interstellar medium caused by AGN outflows (driven by various mechanisms including radiation pressure, accretion disc winds, and jets). We also describe how interpreting observations in the context of theoretical work can be challenging, in part, due to some of the adopted terminology.

Published
2024
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42. What Have We Learned about the Life Cycle of Radio Galaxies from New Radio Surveys

Author

Raffaella Morganti

Subjects
survey–radio continuum, radio continuum, galaxies, active, Astronomy, QB1-991
Abstract

The recurrent activity of radio AGN, with phases of activity alternating with periods of quiescence, has been known since the early studies of these objects. The full relevance of this cycle is emphasised by the requirement, from the AGN feedback scenario, of a recurrent impact of the energy released by the SMBH during the lifetime of the host galaxy: only in this way can AGN feedback influence galaxy evolution. Radio AGN in different evolutionary phases can be identified by their properties, like morphology and spectral indices. Dying/remnant and restarted sources have been the most elusive to select and characterise, but they are crucial to quantify the full life cycle. Thanks to the availability of new, large radio surveys (particularly at low frequencies), it is finally possible to make a more complete census of these rare sources and start building larger samples. This paper gives an overview of the recent work conducted using a variety of radio telescopes and surveys, highlighting some of the new results characterising the properties of dying/remnant and restarted radio sources and what has been learned about the life cycle of radio AGN. The comparison with the predictions from numerical simulations is also discussed. The results so far show that remnant and restarted radio AGN have a variety of properties which make these objects more complex than previously thought.

Published
2024
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44. Dwarf galaxies' black holes behave differently

Subjects
Galaxies, Dwarfs, Astronomy
Abstract

>> All massive galaxies like the Milky Way host super-massive black holes (SMBHs) millions to billions of times the mass of the Sun in their centers. But astronomers aren't yet [...]

Published
2024

45. Why don't we see galaxies rotating?

Author

Baird, Christopher S.

Subjects
Galaxies, Astronomy
Abstract

Humans do not notice the rotational motion of galaxies because galaxies are so unimaginably large. Galaxies are so large it takes them a long time to complete one rotation. For [...]

Published
2024

46. 2a Results: galaxy to cloud scales

Author

Clare Dobbs

Subjects
interstellar medium, galaxies, star formation-galaxies, star formation-HII regions-molecular clouds, numerical simulations, Astronomy, QB1-991, Geophysics. Cosmic physics, QC801-809
Abstract

Simulations from the scales of isolated galaxies to clouds have been instrumental in informing us about molecular cloud formation and evolution. Simulations are able to investigate the roles of gravity, feedback, turbulence, heating and cooling, and magnetic fields on the physics of the interstellar medium, and star formation. Compared to simulations of individual clouds, galactic and sub-galactic scale simulations can include larger galactic scale processes such as spiral arms, bars, and larger supernovae bubbles, which may influence star formation. Simulations show cloud properties and lifetimes in broad agreement with observations. Gravity and spiral arms are required to produce more massive GMCs, whilst stellar feedback, likely photoionisation, leads to relatively short cloud lifetimes. On larger scales, supernovae may be more dominant in driving the structure and dynamics, but photoionisation may still have a role. In terms of the dynamics, feedback is probably the main driver of velocity dispersions, but large scale processes such as gravity and spiral arms may also be significant. Magnetic fields are generally found to decrease star formation on galaxy or cloud scales, and simulations are ongoing to study whether clouds are sub or supercritical on different scales in galaxy scale simulations. Simulations on subgalactic scales, or zoom in simulations, allow better resolution of feedback processes, filamentary structure within clouds, and the study of stellar clusters.

Published
2023
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48. Star-formation Property of High Redshift Galaxies in Clusters: Perceptive View from Observation and Simulation.

Author

Lee, Seong-Kook, Im, Myungshin, Ko, Eunhee, Park, Changbom, Kim, Juhan, Lee, Jaehyun, and Hyun, Minhee

Subjects
*STAR formation, *GALAXIES, *ASTRONOMY, *DENSITY, *CLUSTER theory (Nuclear physics)
Abstract

The evolution of star formation properties of galaxies depends on the environment where galaxies reside, and generally star formation of galaxies in dense environment decreases more quickly. Interestingly, the star formation property of high-redshift galaxies clusters vary largely even though they are at similar redshift. We have found that the large-scale environment surrounding each galaxy cluster can contribute to make this cluster-by-cluster variation. This correlation is found in the results from observational data as well as in the simulations of galaxy formation. We suggest the 'Web-feeding model' to explain this trend. Star-forming galaxies falling into the galaxy cluster from surrounding large-scale structure make the quiescent galaxy fraction of the cluster lower than relatively isolated clusters. [ABSTRACT FROM AUTHOR]

Published
2023
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49. THE NIGHT SKY IN 2024.

Author

Atkinson, Stuart

Subjects
PLANETARY science, GALAXIES, ASTRONOMY, MERCURY, MOON
Abstract

The article focuses on upcoming celestial events and phenomena to observe in the night sky in 2024. It highlights events such as Mercury's greatest separation from the Sun, a celestial pairing of the Moon and Venus, the Moon's proximity to Jupiter, the possible visibility of Comet 12P/Pons-Brooks, and the beginning of galaxy season, providing details and dates for each event.

Published
2023

50. Astronomy

Author

Smith, Robert W., Morris, Emily, Section editor, Scholl, Lesa, editor, and Morris, Emily, editor

Published
2022
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