Showing total 35 results

1. Correction to: Determining star-formation rates in active galactic nuclei hosts via stellar population synthesis.

Author

Riffel, Rogério, Mallmann, Nicolas D, Ilha, Gabriele S, Storchi-Bergmann, Thaisa, Riffel, Rogemar A, Rembold, Sandro B, Bizyaev, Dmitry, do Nascimento, Janaina C, Schimoia, Jaderson S, da Costa, Luiz N, Boardman, Nicholas Fraser, Boquien, Médéric, and Couto, Guilherme S

Subjects

*STELLAR populations, *STAR formation, *ACTIVE galactic nuclei

Abstract

This document is a correction to a paper titled "Determining star-formation rates in active galactic nuclei hosts via stellar population synthesis." The correction addresses an inconsistency in the value of |$H_0$| used in the analysis. The authors have now adopted a uniform value of |$H_0=73.0$| km s|$^{-1}$| Mpc|$^{-1}$| for both star-formation rates (SFR|$_\\star$| and SFR|$_{Gas}$|). As a result, some figures and the transformation equation have been updated. The conclusions of the paper remain unchanged. The document provides the corrected equations and figures for reference. [Extracted from the article]

Published

2024

2. Correction to: Binary black hole mergers from population III stars: uncertainties from star formation and binary star properties.

Author

Santoliquido, Filippo, Mapelli, Michela, Iorio, Giuliano, Costa, Guglielmo, Glover, Simon C O, Hartwig, Tilman, Klessen, Ralf S, and Merli, Lorenzo

Subjects

*BINARY black holes, *STAR formation, *BINARY stars, *MERGERS & acquisitions, *STELLAR populations, *BLACK holes

Abstract

This document is a correction to a previously published paper titled "Binary black hole mergers from population III stars: uncertainties from star formation and binary star properties." The authors discovered a minor bug in the code used to produce the results shown in various figures. The correction provides the updated figures and lists the changes made to the published version. The authors state that the bug did not significantly affect the results and conclusions of the paper. The main data presented in the paper are publicly available on Zenodo and GitLab. [Extracted from the article]

Published

2024

3. The origin of the metallicity distributions of the NE and W stellar shelves in the Andromeda Galaxy.

Author

Milošević, S, Mićić, M, and Lewis, G F

Subjects

*ANDROMEDA Galaxy, *ELLIPTICAL galaxies, *TIDAL currents, *STAR formation, *STELLAR mass

Abstract

Tidal streams and stellar shells are naturally formed in galaxy interactions and mergers. The Giant Stellar Stream (GSS), the North-East (NE), and Western (W) stellar shelves observed in Andromeda Galaxy (M31) are examples of these structures and were formed through the merger of M31 and a satellite galaxy. Recent observational papers have provided strong evidence that the shells and GSS originate from a single progenitor. In this paper, we investigate the formation of these two stellar shelves and the detailed nature of their relationship to the GSS. We present numerical simulations of tidal disruption of a satellite galaxy assuming that it is a progenitor of the GSS and the shell system. We represent the progenitor as a dwarf spheroidal galaxy with the stellar mass of 109 M⊙ and evolve its merger with M31 for 3 Gyr to reproduce the chemodynamical properties of the NE and W shelves. We find that an initial metallicity of the progenitor with a negative radial gradient of ΔFeH  = −0.3 ± 0.2 successfully reproduces observed metallicities of the NE, W shelves, and the GSS, showing that all these structures can originate from the same merger event. [ABSTRACT FROM AUTHOR]

Published

2024

4. The structural properties of nearby dwarf galaxies in low-density environments – size, surface brightness, and colour gradients.

Author

Lazar, I, Kaviraj, S, Watkins, A E, Martin, G, Bichang'a, B, and Jackson, R A

Subjects

*GALACTIC evolution, *GALAXY formation, *STELLAR mass, *STAR formation, *GALAXIES

Abstract

We use a complete sample of 211 nearby (⁠|$z< 0.08$|⁠), dwarf (10 |$^{8}$|  M |$_{\odot }$| < |$M_{\rm {\star }}$| < 10 |$^{9.5}$|  M |$_{\odot }$|⁠) galaxies in low-density environments, to study their structural properties: effective radii (⁠|$R_{\rm e }$|⁠), effective surface brightnesses (⁠|$\langle \mu \rangle _{\rm e}$|⁠), and colour gradients. We explore these properties as a function of stellar mass and the three principal dwarf morphological types identified in a companion paper – early-type galaxies (ETGs), late-type galaxies (LTGs), and featureless systems. The median |$R_{\rm e }$| of LTGs and featureless galaxies are factors of |$\sim$| 2 and |$\sim$| 1.2 larger than the ETGs. While the median |$\langle \mu \rangle _{\rm e}$| of the ETGs and LTGs is similar, the featureless class is |$\sim$| 1 mag arcsec |$^{-2}$| fainter. Although they have similar median |$R_{\rm e }$|⁠ , the featureless and ETG classes differ significantly in their median |$\langle \mu \rangle _{\rm e}$|⁠ , suggesting that their evolution is different and that the featureless galaxies are not a subset of the ETGs. While massive ETGs typically exhibit negative or flat colour gradients, dwarf ETGs generally show positive colour gradients (bluer centres). The growth of ETGs therefore changes from being 'outside-in' to 'inside-out' as we move from the dwarf to the massive regime. The colour gradients of dwarf and massive LTGs are, however, similar. Around 46 per cent of dwarf ETGs show prominent, visually identifiable blue cores which extend out to |$\sim$| 1.5 |$R_{\rm e}$|⁠. Finally, compared to their non-interacting counterparts, interacting dwarfs are larger, bluer at all radii and exhibit similar median |$\langle \mu \rangle _{\rm e}$|⁠ , indicating that interactions typically enhance star formation across the entire galaxy. [ABSTRACT FROM AUTHOR]

Published

2024

5. Magnetic field, magnetospheric accretion, and candidate planet of the young star GM Aurigae observed with SPIRou.

Author

Zaire, B, Donati, J -F, Alencar, S P, Bouvier, J, Moutou, C, Bellotti, S, Carmona, A, Petit, P, Kóspál, Á, Shang, H, Grankin, K, Manara, C, Alecian, E, Gregory, S P, Fouqué, P, and consortium, the SLS

Subjects

*VARIABLE stars, *NATURAL satellites, *INNER planets, *STAR formation, *MAGNETIC dipoles, *STELLAR activity, *STELLAR magnetic fields

Abstract

This paper analyses spectropolarimetric observations of the classical T Tauri star (CTTS) GM Aurigae collected with SPIRou, the near-infrared spectropolarimeter at the Canada–France–Hawaii Telescope, as part of the SLS and SPICE Large Programs. We report for the first time results on the large-scale magnetic field at the surface of GM Aur using Zeeman Doppler imaging. Its large-scale magnetic field energy is almost entirely stored in an axisymmetric poloidal field, which places GM Aur close to other CTTSs with similar internal structures. A dipole of about 730 G dominates the large-scale field topology, while higher order harmonics account for less than 30 per cent of the total magnetic energy. Overall, we find that the main difference between our three reconstructed maps (corresponding to sequential epochs) comes from the evolving tilt of the magnetic dipole, likely generated by non-stationary dynamo processes operating in this largely convective star rotating with a period of about 6 d. Finally, we report a |$5.5\sigma$| detection of a signal in the activity-filtered radial velocity data of semi-amplitude |$110\pm 20$|  m s |$^{-1}$|  at a period of |$8.745\pm 0.009$|  d. If attributed to a close-in planet in the inner accretion disc of GM Aur, it would imply that this planet candidate has a minimum mass of |$1.10 \pm 0.30\, M_\mathrm{Jup}$| and orbits at a distance of |$0.082 \pm 0.002$|  au. [ABSTRACT FROM AUTHOR]

Published

2024

6. Bulge+disc decomposition of HFF and CANDELS galaxies: UVJ diagrams and stellar mass–size relations of galaxy components at 0.2 ≤ z ≤ 1.5.

Author

Nedkova, Kalina V, Häußler, Boris, Marchesini, Danilo, Brammer, Gabriel B, Feinstein, Adina D, Johnston, Evelyn J, Kartaltepe, Jeyhan S, Koekemoer, Anton M, Martis, Nicholas S, Muzzin, Adam, Rafelski, Marc, Shipley, Heath V, Skelton, Rosalind E, Stefanon, Mauro, van der Wel, Arjen, and Whitaker, Katherine E

Subjects

*GALACTIC evolution, *GALACTIC redshift, *STAR formation, *GALAXIES, *REDSHIFT, *STELLAR mass

Abstract

Using deep imaging from the CANDELS and HFF surveys, we present bulge+disc decompositions with galfitm for |$\sim$| 17 000 galaxies over |$0.2 \le z\le 1.5$|⁠. We use various model parameters to select reliable samples of discs and bulges, and derive their stellar masses using an empirically calibrated relation between mass-to-light ratio and colour. Across our entire redshift range, we show that discs follow stellar mass–size relations that are consistent with those of star-forming galaxies, suggesting that discs primarily evolve via star formation. In contrast, the stellar mass–size relations of bulges are mass-independent. Our novel data set further enables us to separate components into star-forming and quiescent based on their specific star formation rates. We find that both star-forming discs and star-forming bulges lie on stellar mass–size relations that are similar to those of star-forming galaxies, while quiescent discs are typically smaller than star-forming discs and lie on steeper relations, implying distinct evolutionary mechanisms. Similar to quiescent galaxies, quiescent bulges show a flattening in the stellar mass–size relation at |$\sim 10^{10}$|  M |$_\odot$|⁠ , below which they show little mass dependence. However, their best-fitting relations have lower normalizations, indicating that at a given mass, bulges are smaller than quiescent galaxies. Finally, we obtain rest-frame colours for individual components, showing that bulges typically have redder colours than discs, as expected. We visually derive UVJ criteria to separate star-forming and quiescent components and show that this separation agrees well with component colour. HFF bulge+disc decomposition catalogues used for these analyses are publicly released with this paper. [ABSTRACT FROM AUTHOR]

Published

2024

7. Predictions for CO emission and the CO-to-H2 conversion factor in galaxy simulations with non-equilibrium chemistry.

Author

Thompson, Oliver A, Richings, Alexander J, Gibson, Brad K, Faucher-Giguère, Claude-André, Feldmann, Robert, and Hayward, Christopher C

Subjects

*DISK galaxies, *MILKY Way, *GALAXIES, *TRACE gases, *STAR formation, *DWARF galaxies

Abstract

Our ability to trace the star-forming molecular gas is important to our understanding of the Universe. We can trace this gas using CO emission, converting the observed CO intensity into the H |$_2$| gas mass of the region using the CO-to-H |$_2$| conversion factor (⁠|$X_{\rm{{\small CO}}}$|⁠). In this paper, we use simulations to study the conversion factor and the molecular gas within galaxies. We analysed a suite of simulations of isolated disc galaxies, ranging from dwarfs to Milky Way-mass galaxies, that were run using the fire-2 subgrid models coupled to the chimes non-equilibrium chemistry solver. We use the non-equilibrium abundances from the simulations, and we also compare to results using abundances assuming equilibrium, which we calculate from the simulation in post-processing. Our non-equilibrium simulations are able to reproduce the relation between CO and H |$_2$| column densities, and the relation between |$X_{\rm{{\small CO}}}$| and metallicity, seen within observations of the Milky Way. We also compare to the xCOLD GASS survey, and find agreement with their data to our predicted CO luminosities at fixed star formation rate. We also find the multivariate function used by xCOLD GASS overpredicts the H |$_2$| mass for our simulations, motivating us to suggest an alternative multivariate function of our fitting, though we caution that this fitting is uncertain due to the limited range of galaxy conditions covered by our simulations. We also find that the non-equilibrium chemistry has little effect on the conversion factor (<5 per cent) for our high-mass galaxies, though still affects the H |$_2$| mass and |$L_{\rm{{\small CO}}}$| by |$\approx$| 25  per cent. [ABSTRACT FROM AUTHOR]

Published

2024

8. Co-evolution of dust grains and protoplanetary disks. II. Structure and evolution of protoplanetary disks: An analytical approach.

Author

Tsukamoto, Yusuke

Subjects

*ANGULAR momentum (Mechanics), *STAR formation, *GRAVITATIONAL instability, *MAGNETIC fields, *MAGNETOHYDRODYNAMICS, *ACCRETION disks, *PROTOPLANETARY disks

Abstract

In our previous study (Tsukamoto et al. 2023b, PASJ, 75, 835), we investigated the formation and early evolution of protoplanetary disks with 3D non-ideal magnetohydrodynamics simulations considering dust growth, and found that the modified equations of the conventional steady accretion disk model that consider magnetic braking, dust growth, and ambipolar diffusion reproduce the disk structure (such as density and vertical magnetic field) obtained from simulations very well. In this paper, as a sequel to our previous study, we analytically investigate the structure and evolution of protoplanetary disks corresponding to Class 0/I young stellar objects using the modified steady accretion disk model combining an analytical model of envelope accretion. We estimate that the disk radius is several astronomical units at the disk formation epoch and increases to several hundred astronomical units at the end of the accretion phase. The disk mass is estimated to be |$0.01 \lesssim M_{\rm disk} \lesssim 0.1 \, M_\odot$| for a disk with a radius of several tens of astronomical units and a mass accretion rate of |$\dot{M}_{\rm disk} \sim 10^{-6} \, M_\odot \,\, {\rm yr^{-1}}$|⁠. These estimates seems to be consistent with recent observations. We also found that, with typical disk ionization rates (ζ ≳ 10−19 s−1) and a moderate mass accretion rate (⁠|$\dot{M}_{\rm disk}\gtrsim 10^{-8} \, M_\odot \,\, {\rm yr^{-1}}$|⁠), magnetorotational instability is suppressed in the disk because of low plasma β and efficient ambipolar diffusion. We argue that the radial profile of specific angular momentum (or rotational velocity) at the disk outer edge should be continuously connected to that of the envelope if the disk evolves by magnetic braking, and should be discontinuous if the disk evolves by an internal angular momentum transport process such as gravitational instability or magnetorotational instability. Future detailed observations of the specific angular momentum profile around the disk outer edge are important for understanding the angular momentum transport mechanism of protoplanetary disks. [ABSTRACT FROM AUTHOR]

Published

2024

9. LMC stars and where to find them: inferring birth radii for external galaxies.

Author

Lu, Yuxi(Lucy), Buck, Tobias, Nidever, David, Ratcliffe, Bridget, Minchev, Ivan, Macciò, Andrea V, and Obreja, Aura

Subjects

*STARS, *GALAXIES, *STAR formation, *STELLAR populations, *GALACTIC evolution

Abstract

It is well known that stars are subject to radial migration, i.e. over time, they move away from their birth location. This dynamical process tends to mix different stellar populations and hence hinders the determination of the true chemical evolution of a galaxy (e.g. metallicity gradients). One way to account for radial migration is to infer stellar birth radii for individual stars. Many attempts to do so have been performed over the last few years, but are limited to the Milky Way, as computing the birth position of stars requires precise measurements of stellar metallicity and age for individual stars that cover large Galactic radii. Fortunately, recent and future surveys will provide numerous opportunities for inferring birth radii for external galaxies such as the LMC. In this paper, we investigate the possibility of doing so using the NIHAO cosmological zoom-in simulations. We find that it is theoretically possible to infer birth radii with a ∼25 per cent median uncertainty for individual stars in galaxies with i) orderliness of the orbits, |$\langle v_\phi \rangle /\sigma _{v} > 2 $|⁠ , ii) a dark matter halo mass greater or equal to approximately the LMC mass (∼2 × 1011  |${\rm M}_\odot$|⁠), and iii) after the average azimuthal velocity of the stellar disc reaches ∼70 per cent of its maximum. From our analysis, we conclude that it is possible and useful to infer birth radii for the LMC and other external galaxies that satisfy the above criteria. [ABSTRACT FROM AUTHOR]

Published

2024

10. Collapsing molecular clouds with tracer particles – II. Collapse histories.

Author

Collins, David C, Le, Dan K, and Jimenez Vela, Luz L

Subjects

*GRAVITATIONAL energy, *STAR formation, *KINETIC energy

Abstract

In order to develop a complete theory of star formation, one essentially needs to know two things: what collapses and how long it takes. This is the second paper in a series, where we query how long a parcel of gas takes to collapse and the process it undergoes. We embed pseudo-Lagrangian tracer particles in simulations of collapsing molecular clouds, identify the particles that end in dense knots, and then examine the collapse history of the gas. We find a nearly universal behaviour of cruise-then-collapse, wherein a core stays at intermediate densities for a significant fraction of its life before finally collapsing. We identify time immediately before each core collapses, |$t_{\rm {sing}}$|⁠ , and examine how it transitions to high density. We find that the time to collapse is uniformly distributed between |$0.25 t_{\rm {ff}}$| and the end of the simulation at |$\sim\!\! 1 t_{\rm {ff}}$|⁠ , and that the duration of collapse is universally short, |$\Delta t \sim 0.1 t_{\rm {ff}}$|⁠ , where |$t_{\rm {ff}}$| is the free-fall time at the mean density. We describe the collapse in three stages: collection, hardening, and singularity. Collection sweeps low-density gas into moderate density. Hardening brings kinetic and gravitational energies into quasi-equipartition. Singularity is the free-fall collapse, forming an envelope in rough energy balance and central overdensity in |$\sim\!\! 0.1 t_{\rm {ff}}$|⁠. [ABSTRACT FROM AUTHOR]

Published

2024

11. Self-consistent modelling of the Milky Way structure using live potentials.

Author

Durán-Camacho, Eva, Duarte-Cabral, Ana, Pettitt, Alex R, Treß, Robin G, Clark, Paul C, Klessen, Ralf S, Bogue, Kamran R J, Smith, Rowan J, and Sormani, Mattia C

Subjects

*MILKY Way, *INTERSTELLAR medium, *TERMINAL velocity, *STAR formation, *STREAMING video & television

Abstract

To advance our understanding of the evolution of the interstellar medium (ISM) of our Galaxy, numerical models of Milky Way (MW) type galaxies are widely used. However, most models only vaguely resemble the MW (e.g. in total mass), and often use imposed analytic potentials (which cannot evolve dynamically). This poses a problem in asserting their applicability for the interpretation of observations of our own Galaxy. The goal of this work is to identify a numerical model that is not only an MW-type galaxy, but one that can mimic some of the main observed structures of our Galaxy, using dynamically evolving potentials, so that it can be used as a base model to study the ISM cycle in a galaxy like our own. This paper introduces a suite of 15 MW-type galaxy models developed using the arepo numerical code, that are compared to Galactic observations of |$^{12}$| CO and H  i emission via longitude–velocity plots, from where we extract and compare the skeletons of major galactic features and the terminal gas velocities. We found that our best-fitting model to the overall structure, also reproduces some of the more specific observed features of the MW, including a bar with a pattern speed of |$30.0 \pm 0.2$| km s |$^{-1}$|  kpc |$^{-1}$|⁠ , and a bar half-length of |$3.2 \pm 0.8$|  kpc. Our model shows large streaming motions around spiral arms, and strong radial motions well beyond the inner bar. This model highlights the complex motions of a dynamic MW-type galaxy and has the potential to offer valuable insight into how our Galaxy regulates the ISM and star formation. [ABSTRACT FROM AUTHOR]

Published

2024

12. A path towards constraining the evolution of the interstellar medium and outflows in the Milky Way using APOGEE.

Author

Sharda, Piyush, Ting, Yuan-Sen, and Frankel, Neige

Subjects

*INTERSTELLAR medium, *MILKY Way, *DISTRIBUTION of stars, *STAR formation, *GALACTIC evolution, *AGE of stars, *ASTROMETRY

Abstract

In recent years, the study of the Milky Way has significantly advanced due to extensive spectroscopic surveys of its stars, complemented by astroseismic and astrometric data. However, it remains disjoint from recent advancements in understanding the physics of the Galactic interstellar medium (ISM). This paper introduces a new model for the chemical evolution of the Milky Way that can be constrained on stellar data, because it combines a state-of-the-art ISM model with a Milky Way stellar disc model. Utilizing a data set of red clump stars from APOGEE, known for their precise ages and metallicities, we concentrate on the last 6 billion years – a period marked by Milky Way's secular evolution. We examine the oxygen abundance in the low- |$\alpha$| disc stars relative to their ages and birth radii, validating or constraining critical ISM parameters that remain largely unexplored in extragalactic observations. The models that successfully reproduce the radius–metallicity distribution and the age–metallicity distribution of stars without violating existing ISM observations indicate a need for modest differential oxygen enrichment in Galactic outflows, meaning that the oxygen abundance of outflows is higher than the local ISM abundance, irrespective of outflow mass loading. The models also suggest somewhat elevated ISM gas velocity dispersion levels over the past 6 billion years compared to galaxies of similar mass. The extra turbulence necessary could result from energy from gas accretion onto the Galaxy, supernovae clustering in the ISM, or increased star formation efficiency per freefall time. This work provides a novel approach to constraining the Galactic ISM and outflows, leveraging the detailed insights available from contemporary Milky Way surveys. [ABSTRACT FROM AUTHOR]

Published

2024

13. Estimation of stellar mass and star formation rate based on galaxy images.

Author

Zhong, Jing, Deng, Zhijie, Li, Xiangru, Wang, Lili, Yang, Haifeng, Li, Hui, and Zhao, Xirong

Subjects

*STAR formation, *GALACTIC evolution, *GALAXIES, *DARK energy, *GALAXY spectra, *STELLAR mass

Abstract

It is crucial for a deeper understanding of the formation and evolution of galaxies in the Universe to study stellar mass (M *) and star formation rate (SFR). Traditionally, astronomers infer the properties of galaxies from spectra, which are highly informative, but expensive and hard to be obtained. Fortunately, modern sky surveys obtained a vast amount of high-spatial-resolution photometric images. The photometric images are obtained relatively economically than spectra, and it is very helpful for related studies if M * and SFR can be estimated from photometric images. Therefore, this paper conducted some preliminary researches and explorations on this regard. We constructed a deep learning model named Galaxy Efficient Network (GalEffNet) for estimating integrated M * and specific star formation rate (sSFR) from Dark Energy Spectroscopic Instrument galaxy images. The GalEffNet primarily consists of a general feature extraction module and a parameter feature extractor. The research results indicate that the proposed GalEffNet exhibits good performance in estimating M * and sSFR, with σ reaching 0.218 and 0.410 dex. To further assess the robustness of the network, prediction uncertainty was performed. The results show that our model maintains good consistency within a reasonable bias range. We also compared the performance of various network architectures and further tested the proposed scheme using image sets with various resolutions and wavelength bands. Furthermore, we conducted applicability analysis on galaxies of various sizes, redshifts, and morphological types. The results indicate that our model performs well across galaxies with various characteristics and indicate its potentials of broad applicability. [ABSTRACT FROM AUTHOR]

Published

2024

14. Unveiling the Cosmic Cradle: clustering and massive star formation in the enigmatic Galactic bubble N59.

Author

Paulson, Sonu Tabitha, Mallick, K K, and Ojha, D K

Subjects

*SUPERGIANT stars, *STAR clusters, *GALAXY formation, *HIGH mass stars, *SPECTRAL energy distribution, *STAR formation

Abstract

In this paper, we have conducted an investigation focused on a segment of the Spitzer mid-infrared bubble N59, specifically referred to as R1 within our study. Situated in the inner Galactic plane, this region stands out for its hosting of five 6.7 GHz methanol masers, as well as numerous compact |$\mathrm{H}\, \rm {{\small II}}$| regions, massive clumps, filaments, and prominent bright rims. As 6.7 GHz masers are closely linked to the initial phases of high-mass star formation, exploring regions that exhibit a high abundance of these maser detections provides an opportunity to investigate relatively young massive star-forming sites. To characterize the R1 region comprehensively, we utilize multiwavelength (archival) data from optical to radio wavelengths, together with 13CO and C18O data. Utilizing the Gaia DR3 data, we estimate the distance towards the bubble to be 4.66 ± 0.70 kpc. By combining near-infrared (NIR) and mid-infrared (MIR) data, we identify 12 Class I and 8 Class II sources within R1. Furthermore, spectral energy distribution (SED) analysis of selected sources reveals the presence of four embedded high-mass sources with masses ranging from 8.70 to 14.20 M⊙. We also identified several O and B-type stars from radio continuum analysis. Our molecular study uncovers two distinct molecular clouds in the region, which, although spatially close, occupy different regions in velocity space. We also find indications of a potential hub-filament system fostering star formation within the confines of R1. Finally, we propose that the feedback from the |$\mathrm{H}\, \rm {{\small II}}$| regions has led to the formation of prominent Bright Rimmed Clouds (BRCs) within our region of interest. [ABSTRACT FROM AUTHOR]

Published

2024

15. Effects of grain magnetic properties and grain growth on synthetic dust polarization of MHD simulations of low-mass Class 0/I YSOs.

Author

Giang, Nguyen Chau and Hoang, Thiem

Subjects

*MAGNETIC properties, *DUST, *BREWSTER'S angle, *MAGNETIC fields, *TRANSCRANIAL magnetic stimulation, *GRAIN, *STAR formation

Abstract

Thermal dust polarization is a powerful tool to probe magnetic fields (⁠|$\boldsymbol{B}$|⁠) and grain properties. However, a systematic study of the dependence of dust polarization on grain properties in protostellar environments is not yet available. In this paper, we post-process a non-ideal MHD simulation of a collapsing protostellar core with our updated POLARIS code to study in detail the effects of iron inclusions and grain growth on thermal dust polarization. We found that superparamagnetic (SPM) grains can produce high polarization degree of |$p \sim 10\!-\!40~{{\ \rm per\ cent}}$| beyond ∼500 au from the protostar because of their efficient alignment by magnetically enhanced radiative torque mechanism. The magnetic field turbulence in the envelope causes the decrease in p with increasing emission intensity I as p ∝ I α with the slope α ∼ −0.3. But within 500 au, SPM grains tend to have inefficient internal alignment and be aligned with |$\boldsymbol{B}$| by RATs only, producing lower |$p \sim 1~{{\ \rm per\ cent}}$| and a steeper slope of α ∼ −0.6. For paramagnetic (PM) grains, the alignment loss of grains above |$1\, {\mu \rm {m}}$| in the inner ∼200 au produces |$p \lt \lt 1~{{\ \rm per\ cent}}$| and the polarization hole with α ∼ −0.9. Grain growth can increase p in the envelope for SPM grains, but cause stronger depolarization for SPM grains in the inner ∼500 au and for PM grains in the entire protostellar core. Finally, we found the increase of polarization angle dispersion function S with iron inclusions and grain growth, implying the dependence of B-field strength measured using the David–Chandrasekhar–Fermi technique on grain alignment and grain properties. [ABSTRACT FROM AUTHOR]

Published

2024

16. Decaying turbulence in molecular clouds: how does it affect filament networks and star formation?

Author

Dhandha, Jiten, Faes, Zoe, and Smith, Rowan J

Subjects

*STAR formation, *MOLECULAR clouds, *FIBERS, *TURBULENCE, *GRAVITATIONAL potential, *BROWN dwarf stars

Abstract

The fragmentation of gas to form stars in molecular clouds is intrinsically linked to the turbulence within them. These internal motions are set at the birth of the cloud and may vary with galactic environment and as the cloud evolves. In this paper, we introduce a new suite of 15 high-resolution 3D molecular cloud simulations using the moving mesh code arepo to investigate the role of different decaying turbulent modes (mixed, compressive, and solenoidal) and virial ratios on the evolution of a |$10^4\, \mathrm{M}_{\odot }$| molecular cloud. We find that diffuse regions maintain a strong relic of the initial turbulent mode, whereas the initial gravitational potential dominates dense regions. Solenoidal seeded models thus give rise to a diffuse cloud with filament-like morphology, and an excess of brown dwarf mass fragments. Compressive seeded models have an early onset of star-formation, centrally condensed morphologies and a higher accretion rate, along with overbound clouds. 3D filaments identified using disperse and analysed through a new python toolkit we develop and make publicly available with this work called fiesta , show no clear trend in lengths, masses and densities between initial turbulent modes. Overbound clouds, however, produce more filaments and thus have more mass in filaments. The hubs formed by converging filaments are found to favour star-formation, with surprisingly similar mass distributions independent of the number of filaments connecting the hub. [ABSTRACT FROM AUTHOR]

Published

2024

17. Adding value to JWST spectra and photometry: stellar population and star formation properties of spectroscopically confirmed JADES and CEERS galaxies at z > 7.

Author

Duan, Qiao, Conselice, Christopher J, Li, Qiong, Harvey, Thomas, Austin, Duncan, Ormerod, Katherine, Trussler, James, and Adams, Nathan

Subjects

*STELLAR photometry, *STAR formation, *STELLAR populations, *STELLAR spectra, *GALAXIES, *STARBURSTS, *REDSHIFT

Abstract

In this paper, we discuss measurements of the stellar population and star-forming properties for 43 spectroscopically confirmed publicly available high-redshift z > 7 JWST galaxies in the JADES and CEERS observational programs. We carry out a thorough study investigating the relationship between spectroscopic features and photometrically derived ones, including from spectral energy distribution (SED) fitting of models, as well as morphological and structural properties. We find that the star formation rates (SFRs) measured from H β line emission are higher than those estimated from Bayesian SED fitting and ultraviolet (UV) luminosity, with ratios SFRH β/SFRUV ranging from ∼2 to 13. This is a sign that the star formation history is consistently rising given the time-scales of H β versus UV star formation probes. In addition, we investigate how well equivalent widths (EWs) of H β λ4861, [O  iii ] λ4959, and [O  iii ] λ5007 can be measured from photometry, finding that, on average, the EW derived from photometric excesses in filters is 30 per cent smaller than the direct spectroscopic measurement. We also discover that a stack of the line emitting galaxies shows a distinct morphology after subtracting imaging that contains only the continuum. This gives us a first view of the line or ionized gas emission from z > 7 galaxies, demonstrating that this material has a similar distribution, statistically, as the continuum. We also compare the derived SFRs and stellar masses for both parametric and non-parametric star formation histories, where we find that 35 per cent of our sample formed at least 30 per cent of their stellar mass in recent (<10 Myr) starburst events. [ABSTRACT FROM AUTHOR]

Published

2024

18. Clumpy structures within the turbulent primordial cloud.

Author

Tang, Ching-Yao and Chen, Ke-Jung

Subjects

*MACH number, *STAR formation, *TURBULENCE, *GALAXY formation, *STELLAR populations, *STOCHASTIC models

Abstract

The primordial clouds in the mini-haloes hatch the first generation stars of the Universe, which play a crucial role in cosmic evolution. In this paper, we investigate how turbulence impacts the structure of primordial star-forming clouds. Previous cosmological simulations of the first star formation predicted a typical mass of around |$\mathrm{ 100 \, M_\odot }$|⁠. This conflicts with recent observations of extremely metal-poor stars, suggesting a lower mass scale of about |$\mathrm{25 \, M_\odot }$|⁠. The discrepancy may arise from unresolved turbulence in the star-forming cloud, driven by primordial gas accretion during mini-halo formation in the previous simulations. To quantitatively examine the turbulence effect on the primordial cloud formation, we employ the adaptive mesh refinement code Enzo to model the gas cloud with primordial composition, including artificially driven turbulence on the cloud scale and relevant gas physics. This artificially driven turbulence utilizes a stochastic forcing model to mimic the unresolved turbulence inside mini-haloes. Our results show that the turbulence with high Mach number and compressional mode effectively fragments the cloud into several clumps, each with dense cores of |$\mathrm{22.7 - 174.9 \, M_\odot }$| that undergo Jeans instability to form stars. Fragmentation caused by intense and compressive turbulence prevents a runaway collapse of the cloud. The self-bound clumps with smaller masses in the turbulent primordial clouds suggest a possible pathway to decrease the theoretical mass scale of the first stars, further reconciling the mass discrepancy between simulations and observations. [ABSTRACT FROM AUTHOR]

Published

2024

19. The dynamical evolution of star-forming regions measured with INDICATE.

Author

Blaylock-Squibbs, George A and Parker, Richard J

Subjects

*STELLAR evolution, *STAR clusters, *STAR formation, *STELLAR dynamics

Abstract

Observations of star-forming regions provide snapshots in time of the star formation process, and can be compared with simulation data to constrain the initial conditions of star formation. In order to make robust inferences, different metrics must be used to quantify the spatial and kinematic distributions of stars. In this paper, we assess the suitability of the INdex to Define Inherent Clustering And TEndencies (INDICATE) method as a diagnostic to infer the initial conditions of star-forming regions that subsequently undergo dynamical evolution. We use INDICATE to measure the degree of clustering in N -body simulations of the evolution of star-forming regions with different initial conditions. We find that the clustering of individual stars, as measured by INDICATE, becomes significantly higher in simulations with higher initial stellar densities, and is higher in subvirial star-forming regions where significant amounts of dynamical mixing have occurred. We then combine INDICATE with other methods that measure the mass segregation (ΛMSR), relative stellar surface density ratio (ΣLDR), and the morphology (Q -parameter) of star-forming regions, and show that the diagnostic capability of INDICATE increases when combined with these other metrics. [ABSTRACT FROM AUTHOR]

Published

2024

20. Search for brown dwarfs in IC 1396 with Subaru HSC: interpreting the impact of environmental factors on substellar population.

Author

Gupta, Saumya, Jose, Jessy, Das, Swagat R, Guo, Zhen, Damian, Belinda, Prakash, Prem, and Samal, Manash R

Subjects

*BROWN dwarf stars, *MACHINE learning, *STELLAR mass, *SPECIFIC gravity, *STAR formation, *DWARF stars, *SCIENTIFIC community

Abstract

Young stellar clusters are predominantly the hub of star formation and hence, ideal to perform comprehensive studies over the least explored substellar regime. Various unanswered questions like the mass distribution in brown dwarf regime and the effect of diverse cluster environment on brown dwarf formation efficiency still plague the scientific community. The nearby young cluster, IC 1396 with its feedback-driven environment, is ideal to conduct such study. In this paper, we adopt a multiwavelength approach, using deep Subaru HSC along with other data sets and machine learning techniques to identify the cluster members complete down to ∼ 0.03 M⊙ in the central 22 arcmin area of IC 1396. We identify 458 cluster members including 62 brown dwarfs which are used to determine mass distribution in the region. We obtain a star-to-brown dwarf ratio of ∼ 6 for a stellar mass range 0.03–1 M⊙ in the studied cluster. The brown dwarf fraction is observed to increase across the cluster as radial distance from the central OB-stars increases. This study also compiles 15 young stellar clusters to check the variation of star-to-brown dwarf ratio relative to stellar density and ultraviolet (UV) flux ranging within 4–2500 stars pc−2 and 0.7–7.3  G 0, respectively. The brown dwarf fraction is observed to increase with stellar density but the results about the influence of incident UV flux are inconclusive within this range. This is the deepest study of IC 1396 as of yet and it will pave the way to understand various aspects of brown dwarfs using spectroscopic observations in future. [ABSTRACT FROM AUTHOR]

Published

2024

21. Efficient selection of gravitationally lensed OH megamasers with MeerKAT and the Square Kilometre Array.

Author

Button, Charissa B and Deane, Roger P

Subjects

*MEERKAT, *GALAXY mergers, *SPECTRAL lines, *SUPERMASSIVE black holes, *ACTINIC flux, *STAR formation, *SPECTRAL energy distribution

Abstract

There has been a recent resurgence in hydroxyl (OH) megamaser research driven by Square Kilometre Array (SKA) precursor/pathfinder telescopes. This will continue in the lead-up to the SKA mid-frequency array, which will greatly expand our view of OH megamasers and their cosmic evolution over ≳80 per cent of the age of the Universe. This is expected to yield large scientific returns as OH megamasers trace galaxy mergers, extreme star formation, high molecular gas densities, and potentially binary/dual supermassive black hole systems. In this paper, we predict the distortion to the OH luminosity function that a magnification bias will inflict, and in turn, predict the distortion on the OH megamaser number counts as a function of redshift. We identify spectral flux density thresholds that will enable efficient lensed OH megamaser selection in large spectral line surveys with MeerKAT and SKA. The surface density of lensed galaxies that could be discovered in this way is a strong function of the redshift evolution of the OH megamaser luminosity function, with predictions as high as ∼1 lensed OH source per square degree at high redshifts (z ≳ 1) for anticipated SKA spectral line survey designs. This could enable efficient selection of some of the most highly obscured galaxies in the Universe. This high-redshift selection efficiency, in combination with the large survey speed of the SKA at ≲1 GHz frequencies and the high magnifications possible with compact OH emission regions (μOH ≫ 10), will enable a transformational view of OH in the Universe. [ABSTRACT FROM AUTHOR]

Published

2024

22. The Giant Molecular Cloud G148.24+00.41: gas properties, kinematics, and cluster formation at the nexus of filamentary flows.

Author

Rawat, Vineet, Samal, M R, Walker, D L, Ojha, D K, Tej, A, Zavagno, A, Zhang, C P, Elia, Davide, Dutta, S, Jose, J, Eswaraiah, C, and Sharma, E

Subjects

*MOLECULAR clouds, *KINEMATICS, *STAR formation, *STELLAR evolution

Abstract

Filamentary flows towards the centre of molecular clouds have been recognized as a crucial process in the formation and evolution of stellar clusters. In this paper, we present a comprehensive observational study that investigates the gas properties and kinematics of the Giant Molecular Cloud G148.24+00.41 using the observations of CO (1-0) isotopologues. We find that the cloud is massive (105 M⊙) and is one of the most massive clouds of the outer Galaxy. We identified six likely velocity coherent filaments in the cloud having length, width, and mass in the range of 14–38 pc, 2.5–4.2 pc, and (1.3–6.9) × 103 M⊙, respectively. We find that the filaments are converging towards the central area of the cloud, and the longitudinal accretion flows along the filaments are in the range of ∼ 26–264 M⊙ Myr−1. The cloud has fragmented into seven clumps having mass in the range of ∼ 260–2100 M⊙ and average size around ∼ 1.4 pc, out of which the most massive clump is located at the hub of the filamentary structures, near the geometric centre of the cloud. Three filaments are found to be directly connected to the massive clump and transferring matter at a rate of ∼ 675 M⊙ Myr−1. The clump hosts a near-infrared cluster. Our results show that large-scale filamentary accretion flows towards the central region of the collapsing cloud is an important mechanism for supplying the matter necessary to form the central high-mass clump and subsequent stellar cluster. [ABSTRACT FROM AUTHOR]

Published

2024

23. The dual role of outflows in quenching satellites of low-mass hosts: NGC 3109.

Author

Garling, Christopher T, Peter, Annika H G, Spekkens, Kristine, Sand, David J, Hargis, Jonathan, Crnojević, Denija, and Carlin, Jeffrey L

Subjects

*INTERSTELLAR medium, *DWARF galaxies, *MILKY Way, *STARS, *GALAXY formation, *STAR formation, *GALACTIC evolution

Abstract

While dwarf galaxies observed in the field are overwhelmingly star forming, dwarf galaxies in environments as dense or denser than the Milky Way are overwhelmingly quenched. In this paper, we explore quenching in the lower density environment of the Small-Magellanic-Cloud-mass galaxy NGC 3109 (M |$_* \sim 10^8 \, \text{M}_\odot$|⁠), which hosts two known dwarf satellite galaxies (Antlia and Antlia B), both of which are |${\rm H}\, \rm{\small I}$| deficient compared to similar galaxies in the field and have recently stopped forming stars. Using a new semi-analytic model in concert with the measured star formation histories and gas masses of the two dwarf satellite galaxies, we show that they could not have been quenched solely by direct ram pressure stripping of their interstellar media, as is common in denser environments. Instead, we find that separation of the satellites from pristine gas inflows, coupled with stellar-feedback-driven outflows from the satellites (jointly referred to as the starvation quenching model), can quench the satellites on time-scales consistent with their likely infall times into NGC 3109's halo. It is currently believed that starvation is caused by 'weak' ram pressure that prevents low-density, weakly bound gas from being accreted on to the dwarf satellite, but cannot directly remove the denser interstellar medium. This suggests that star-formation-driven outflows serve two purposes in quenching satellites in low-mass environments: outflows from the host form a low-density circumgalactic medium that cannot directly strip the interstellar media from its satellites, but is sufficient to remove loosely bound gaseous outflows from the dwarf satellites driven by their own star formation. [ABSTRACT FROM AUTHOR]

Published

2024

24. Modelling JWST mid-infrared counts: excellent consistency with models derived for IRAS, ISO, and Spitzer.

Author

Rowan-Robinson, Michael

Subjects

*GALACTIC evolution, *SUBMILLIMETER astronomy, *STAR formation, *STARBURSTS, *GALAXIES

Abstract

Models derived in 2009 to fit mid-infrared (8–24 micron) source counts from the IRAS, ISO, and Spitzer missions, provide an excellent fit to deep counts with JWST , demonstrating that the evolution of dusty star-forming galaxies is well understood. The evolution of dust in galaxies at high redshifts is discussed and a simple prescription is proposed to model this. This allows more realistic models for source-counts at submillimetre wavelength. A reasonable fit to 250, 500, 850, and 1100 micron counts is obtained. This paper therefore draws together the IRAS, ISO, Spitzer, Akari, Herschel , submillimetre ground-based, and JWST surveys into a single picture. [ABSTRACT FROM AUTHOR]

Published

2024

25. Quokka-based understanding of outflows (QED) – I. Metal loading, phase structure, and convergence testing for solar neighbourhood conditions.

Author

Vijayan, Aditi, Krumholz, Mark R, and Wibking, Benjamin D

Subjects

*INTERSTELLAR medium, *NEIGHBORHOODS, *IONIZED gases, *METALS, *BLAST effect, *STAR formation, *QUANTUM electrodynamics

Abstract

Multiphase galactic outflows, generated by supernova (SN) feedback, are likely to be more metal rich than the interstellar media from which they are driven due to incomplete mixing between SN ejecta and the ambient interstellar medium. This enrichment is important for shaping galactic metallicities and metallicity gradients, but measuring it quantitatively from simulations requires resolution high enough to resolve mass, momentum and energy exchanges between the different phases of the outflows. In this context, we present QED, which are simulations of outflows, driven by SN feedback, conducted using Quokka , a new GPU-optimized adaptive mesh refinement radiation-hydrodynamics code. This code allows us to reach combinations of resolution, simulation volume, and simulation duration larger than those that have previously been possible, and to resolve all gas phases from cold neutral medium, T ∼ 100 K, to hot ionized gas, T ≳ 107 K. In this, a first of a series of papers exploring generation and evolution of multiphase outflows from a wide range of galactic environments and star formation rates, we quantify the extent of selective metal loading in solar neighbourhood-like environments. We explain the selective metal loading, we find as a result of the transport of metals within and between phases, a phenomenon we can study owing to the parsec-scale resolution that our simulations achieve. We also quantify the sensitivity of metal loading studies to numerical resolution, and present convergence criteria for future studies. [ABSTRACT FROM AUTHOR]

Published

2024

26. Dark-ages reionization and galaxy formation simulation – XXI. Constraining the evolution of the ionizing escape fraction.

Author

Mutch, Simon J, Greig, Bradley, Qin, Yuxiang, Poole, Gregory B, and Wyithe, J Stuart B

Subjects

*GALAXY formation, *INTERSTELLAR medium, *GALACTIC redshift, *COSMIC background radiation, *STELLAR mass, *STAR formation

Abstract

The fraction of ionizing photons that escape their host galaxies to ionize hydrogen in the intergalactic medium (IGM) is a critical parameter in analyses of the reionization era. In this paper, we use the meraxes semi-analytic galaxy formation model to infer the mean ionizing photon escape fraction and its dependence on galaxy properties through joint modelling of the observed high redshift galaxy population and existing constraints on the reionization history. Using a Bayesian framework, and under the assumption that escape fraction is primarily related to halo mass, we find that the joint constraints of the ultraviolet luminosity function, cosmic microwave background optical depth, and the Ly α forest require an escape fraction of |$(18\pm 5)$| per cent for galaxies within haloes of M ≲ 109 M⊙ and |$(5\pm 2)$| per cent for more massive haloes. In terms of galaxy properties, this transition in escape fraction occurs at stellar masses of M ⋆ ∼ 107 M⊙, nearly independent of redshift. As a function of redshift, reionization is dominated by the smaller M ⋆ ≲ 107 M⊙ galaxies with high escape fractions at z ≳ 6 and by the larger M ⋆ ≳ 107 M⊙ galaxies with lower escape fractions at z ≲ 6. Galaxies with star formation rates of 10−2.5 M⊙yr−1 to 10−1.5 M⊙yr−1 provide the dominant source of ionizing photons throughout reionization. Our results are consistent with recent direct measurements of a |$\sim 5~{{\ \rm per\ cent}}$| escape fraction from massive galaxies at the end of reionization and support the picture of low mass galaxies being the dominant sources of ionizing photons during reionization. [ABSTRACT FROM AUTHOR]

Published

2024

27. INSPIRE: INvestigating Stellar Population In RElics – V. A catalogue of ultra-compact massive galaxies outside the local Universe and their degree of relicness.

Author

Spiniello, C, D'Ago, G, Coccato, L, Hartke, J, Tortora, C, Ferré-Mateu, A, Pulsoni, C, Cappellari, M, Maksymowicz-Maciata, M, Arnaboldi, M, Bevacqua, D, Gallazzi, A, Hunt, L K, La Barbera, F, Martín-Navarro, I, Napolitano, N R, Radovich, M, Saracco, P, Scognamiglio, D, and Spavone, M

Subjects

*STELLAR populations, *GALAXIES, *RELICS, *STAR formation, *STELLAR mass, *AGE of stars, UNIVERSE

Abstract

This paper presents the third data release of the INvestigating Stellar Population In RElics (INSPIRE) project, comprising 52 ultra-compact massive galaxies (UCMGs) observed with the X-Shooter spectrograph. We measure integrated stellar velocity dispersion, [Mg/Fe] abundances, ages, and metallicities for all the INSPIRE objects. We thus infer star formation histories and confirm the existence of a degree of relicness (DoR), defined in terms of the fraction of stellar mass formed by z  = 2, the time at which a galaxy has assembled 75 per cent of its mass, and the final assembly time. Objects with a high DoR assembled their stellar mass at early epochs, while low-DoR objects show a non-negligible fraction of later formed populations and hence a spread in ages and metallicities. A higher DoR correlates with larger [Mg/Fe], supersolar metallicity, and larger velocity dispersion values. The 52 UMCGs span a large range of DoR from 0.83 to 0.06, with 38 of them having formed more than 75  per cent of their mass by z  = 2. Of these, nine are extreme relics (DoR>0.7), since they formed the totality (⁠|$\gt 99~{{\ \rm per\ cent}}$|⁠) of their stellar mass by redshift z  = 2. The remaining 14 UCMGs cannot be considered relics, as they are characterized by more extended star formation histories. With INSPIRE  we built the first sizeable sample of relics outside the local Universe, up to z ∼ 0.4, increasing the number of confirmed relics by a factor of >10, and opening up an important window to explain the mass assembly of massive galaxies in the high- z Universe. [ABSTRACT FROM AUTHOR]

Published

2024

28. The metallicity dependence of the stellar initial mass function.

Author

Tanvir, Tabassum S and Krumholz, Mark R

Subjects

*STELLAR initial mass function, *STELLAR radiation, *STELLAR luminosity function, *STAR formation

Abstract

During star formation, dust plays the crucial role of coupling gas to stellar radiation fields, allowing radiation feedback to influence gas fragmentation and thus the stellar initial mass function (IMF). Variations in dust abundance therefore provide a potential avenue by which variation in galaxy metallicity might affect the IMF. In this paper, we present a series of radiation-magnetohydrodynamic simulations in which we vary the metallicity and thus the dust abundance from 1 per cent of solar to 3× solar, spanning the range from the lowest metallicity dwarfs to the most metal-rich early-type galaxies (ETGs) found in the local Universe. We design the simulations to keep all dimensionless parameters constant so that the interaction between feedback and star-forming environments of varying surface density and metallicity is the only factor capable of breaking the symmetry between the simulations and modifying the IMF, allowing us to isolate and understand the effects of each environmental parameter cleanly. We find that shifts in the IMF with varying metallicity at a fixed surface density are smaller than the shifts in varying surface density at a fixed surface metallicity. We also find that metallicity-induced IMF variations are too small to explain the mass-to-light ratio shifts seen in the ETGs. We therefore conclude that metallicity variations are much less important than variations in surface density in driving changes in the IMF and that the latter rather than the former are most likely responsible for the IMF variations found in ETGs. [ABSTRACT FROM AUTHOR]

Published

2024

29. The first fireworks: A roadmap to Population III stars during the epoch of reionization through pair-instability supernovae.

Author

Venditti, Alessandra, Bromm, Volker, Finkelstein, Steven L, Graziani, Luca, and Schneider, Raffaella

Subjects

*SUPERNOVAE, *STELLAR mass, *STARS, *STAR formation, *STELLAR populations, *FIREWORKS

Abstract

With the launch of JWST and other scheduled missions aimed at probing the distant universe, we are entering a new promising era for high- z astronomy. One of our main goals is the detection of the first population of stars (Population III or Pop III stars), and models suggest that Pop III star formation is allowed well into the Epoch of Reionization (EoR), rendering this an attainable achievement. In this paper, we focus on our chance of detecting massive Pop IIIs at the moment of their death as Pair-Instability Supernovae (PISNe). We estimate the probability of discovering PISNe during the EoR in galaxies with different stellar masses (7.5 ≤ Log(M ⋆/M⊙) ≤ 10.5) from six dustyGadget simulations of 50  h −1 cMpc per side. We further assess the expected number of PISNe in surveys with JWST/NIRCam and Roman/WFI. On average, less than one PISN is expected in all examined JWST fields at z ≃ 8 with Δ z  = 1, and O(1) PISN may be found in a ∼1 deg2 Roman field in the best-case scenario, although different assumptions on the Pop III IMF and/or Pop III star formation efficiency can decrease this number substantially. Including the contribution from unresolved low-mass haloes holds the potential for increased discoveries. JWST/NIRCam and Roman/WFI allow the detection of massive-progenitor (∼250 M⊙) PISNe throughout all the optimal F200W-F356W, F277W-F444W, and F158-F213 colours. PISNe are also pre-dominantly located at the outskirts of their hosting haloes, facilitating the disentangling of underlying stellar emission thanks to the spatial-resolution capabilities of the instruments. [ABSTRACT FROM AUTHOR]

Published

2024

30. The motivation for flexible star-formation histories from spatially resolved scales within galaxies.

Author

Jain, Shweta, Tacchella, Sandro, and Mosleh, Moein

Subjects

*STAR formation, *STELLAR mass, *GALAXIES, *STELLAR populations, *SPECTRAL energy distribution, *AGE of stars

Abstract

The estimation of galaxy stellar masses depends on the assumed prior of the star-formation history (SFH) and spatial scale of the analysis (spatially resolved versus integrated scales). In this paper, we connect the prescription of the SFH in the spectral energy distribution (SED) fitting to spatially resolved scales (∼kpc) to shed light on the systematics involved when estimating stellar masses. Specifically, we fit the integrated photometry of ∼970 massive (log (M⋆/M⊙) = 9.8–11.5), intermediate redshift (z  = 0.5–2.0) galaxies with PROSPECTOR , assuming both exponentially declining tau model and flexible SFHs. We complement these fits with the results of spatially resolved SFH estimates obtained by pixel-by-pixel SED fitting, which assume tau models for individual pixels. These spatially resolved SFHs show a large diversity in shapes, which can largely be accounted for by the flexible SFHs with PROSPECTOR. The differences in the stellar masses from those two approaches are overall in good agreement (average difference of ∼0.07 dex). Contrarily, the simpler tau model SFHs typically miss the oldest episode of star formation, leading to an underestimation of the stellar mass by ∼0.3 dex. We further compare the derived global specific star-formation rate (sSFR), the mass-weighted stellar age (t50), and the star-formation time-scale (τSF) obtained from the different SFH approaches. We conclude that the spatially resolved scales within galaxies motivate a flexible SFH on global scales to account for the diversity of SFHs and counteract the effects of outshining of older stellar populations by younger ones. [ABSTRACT FROM AUTHOR]

Published

2024

31. Illuminating evaporating protostellar outflows: ERIS/SPIFFIER reveals the dissociation and ionization of HH 900.

Author

Reiter, Megan, Haworth, Thomas J, Manara, Carlo F, Ramsay, Suzanne, Klaassen, Pamela D, Itrich, Dominika, and McLeod, Anna F

Subjects

*STAR formation, *IMAGE analysis, *SPECTROGRAPHS, *PROTOSTARS, *PHOTOEXCITATION

Abstract

Protostellar jets and outflows are signposts of active star formation. In H  ii regions, molecular tracers like CO only reveal embedded portions of the outflow. Outside the natal cloud, outflows are dissociated, ionized, and eventually completely ablated, leaving behind only the high-density jet core. Before this process is complete, there should be a phase where the outflow is partially molecular and partially ionized. In this paper, we capture the HH 900 outflow while this process is in action. New observations from the Enhanced Resolution Imager and Spectrograph/SPIFFIER near-infrared (IR) integral field unit spectrograph using the K-middle filter (λ = 2.06–2.34 μ m) reveal H2 emission from the dissociating outflow and Br-γ tracing its ionized skin. Both lines trace the wide-angle outflow morphology but H2 only extends ∼5000 au into the H  ii region while Br-γ extends the full length of the outflow (∼12 650 au), indicating rapid dissociation of the molecules. H2 has higher velocities further from the driving source, consistent with a jet-driven outflow. Diagnostic line ratios indicate that photoexcitation, not just shocks, contributes to the excitation in the outflow. We argue that HH 900 is the first clear example of an evaporating molecular outflow and predict that a large column of neutral material that may be detectable with Atacama Large Millimeter Array accompanies the dissociating molecules. Results from this study will help guide the interpretation of near-IR images of externally irradiated jets and outflows such as those obtained with the JWST in high-mass star-forming regions where these conditions may be common. [ABSTRACT FROM AUTHOR]

Published

2024

32. Arkenstone – I. A novel method for robustly capturing high specific energy outflows in cosmological simulations.

Author

Smith, Matthew C, Fielding, Drummond B, Bryan, Greg L, Kim, Chang-Goo, Ostriker, Eve C, Somerville, Rachel S, Stern, Jonathan, Su, Kung-Yi, Weinberger, Rainer, Hu, Chia-Yu, Forbes, John C, Hernquist, Lars, Burkhart, Blakesley, and Li, Yuan

Subjects

*WIND power, *INTERSTELLAR medium, *SPATIAL resolution, *STAR formation, *COUPLING schemes

Abstract

Arkenstone is a new model for multiphase, stellar feedback-driven galactic winds designed for inclusion in coarse resolution cosmological simulations. In this first paper of a series, we describe the features that allow Arkenstone to properly treat high specific energy wind components and demonstrate them using idealized non-cosmological simulations of a galaxy with a realistic circumgalactic medium (CGM), using the arepo code. Hot, fast gas phases with low mass loadings are predicted to dominate the energy content of multiphase outflows. In order to treat the huge dynamic range of spatial scales involved in cosmological galaxy formation at feasible computational expense, cosmological volume simulations typically employ a Lagrangian code or else use adaptive mesh refinement with a quasi-Lagrangian refinement strategy. However, it is difficult to inject a high specific energy wind in a Lagrangian scheme without incurring artificial burstiness. Additionally, the low densities inherent to this type of flow result in poor spatial resolution. Arkenstone addresses these issues with a novel scheme for coupling energy into the transition region between the interstellar medium (ISM) and the CGM, while also providing refinement at the base of the wind. Without our improvements, we show that poor spatial resolution near the sonic point of a hot, fast outflow leads to an underestimation of gas acceleration as the wind propagates. We explore the different mechanisms by which low and high specific energy winds can regulate the star formation rate of galaxies. In future work, we will demonstrate other aspects of the Arkenstone model. [ABSTRACT FROM AUTHOR]

Published

2024

33. Correction to: Resolving cosmic star formation histories of present-day bulges, discs, and spheroids with P ro F use.

Author

Bellstedt, Sabine, Robotham, Aaron S G, Driver, Simon P, Lagos, Claudia del P, Davies, Luke J M, and Cook, Robin H W

Subjects

*STAR formation, *GALACTIC bulges, *ELLIPTICAL galaxies

Abstract

This document is a correction to a previous article by Bellstedt et al. regarding the cosmic star formation histories of bulges, discs, and spheroids in galaxies. The correction addresses an error in the dust parameters presented in tables 2, 3, and 4 of the original paper. Specifically, the |$\\tau _{\\rm birth}$| and |$\\tau _{\\rm screen}$| values were mistakenly swapped for each component. The corrected values are provided in updated tables 1, 2, and 3. These corrections do not impact any other aspect of the original paper and reflect the settings used to generate the original results. [Extracted from the article]

Published

2024

34. Correction to: The formation of early-type galaxies through monolithic collapse of gas clouds in Milgromian gravity.

Author

Eappen, Robin, Kroupa, Pavel, Wittenburg, Nils, Haslbauer, Moritz, and Famaey, Benoit

Subjects

*GALACTIC evolution, *ELLIPTICAL galaxies, *GRAVITY, *STAR formation

Abstract

This document is a correction to a paper titled "The formation of early-type galaxies through monolithic collapse of gas clouds in Milgromian gravity." The correction addresses an error in equation (8) on page 1083 of the paper. The error does not affect the results or conclusions of the study, but it is important to use the correct equation in future studies to avoid mistakes. The correct equation is provided in the document. The authors of the paper are Robin Eappen, Pavel Kroupa, Nils Wittenburg, Moritz Haslbauer, and Benoit Famaey. [Extracted from the article]

Published

2024

35. Correction to: On the initial mass–radius relation of stellar clusters.

Author

Choksi, Nick and Kruijssen, J M Diederik

Subjects

*GLOBULAR clusters, *GALAXY clusters, *GALAXY formation, *STAR formation, *STAR clusters

Abstract

Keywords: errata; addenda; stars: formation; globular clusters: general; galaxies: formation; galaxies: star clusters: generalThis is an erratum to the paper 'On the initial mass–radius relation of stellar clusters' (2021, MNRAS, 507, 5492–5506). In the originally published version of this manuscript, there was an error in the article title. The correct title is: 'On the initial mass–radius relation of stellar clusters'.This error has been corrected.By Nick Choksi and J M Diederik KruijssenReported by Author; Author [Extracted from the article]

Published

2024