Your search keyword '"Pawlowski, Marcel S"' showing total 13 results

1. Lopsided distribution of MATLAS and ELVES dwarf satellite systems around isolated host galaxies.

Author

Heesters, Nick, Jerjen, Helmut, Müller, Oliver, Pawlowski, Marcel S., and Jamie Kanehisa, Kosuke

Subjects

LARGE scale structure (Astronomy), SATELLITE positioning, DARK matter, GALAXIES, MODELS & modelmaking, DWARF galaxies

Abstract

The properties of satellite dwarf galaxies provide important empirical insights for verifying cosmological models on galaxy scales. Their phase-space correlations, in particular, offer interesting insights into a broad range of models, since they are dominated by gravity and are largely independent of the specific dark matter flavor or baryonic processes that are considered. Next to the much-debated planes-of-satellites phenomenon, the lopsided distribution of satellites relative to their host galaxy has been studied observationally and in cosmological simulations. The degree to which observed lopsidedness is consistent with expectations from simulations is still unclear. We quantified the level of lopsidedness in isolated observed satellite systems under six different metrics. We studied 47 systems from the MATLAS survey beyond the local volume (LV) as well as 21 LV satellite systems from the ELVES survey. The satellite systems are complete to an estimated absolute magnitude of M ∼ −9. We find that the so-called wedge metric, counting the number of dwarfs in wedges with varying opening angles, is best suited to capture a system's overall lopsidedness. Under this metric, our analysis reveals that ∼16 percent of the tested satellite systems exhibit a statistically significant degree of lopsidedness when compared to systems with randomly generated satellite position angles. This presents a notable excess over the expected 5% (2σ level) of significantly lopsided systems in a sample with no overall inherent lopsidedness. To gain the most rounded picture, however, a combination of metrics that are sensitive to different features of lopsidedness should be used. Combining all tested metrics, the number of significantly lopsided systems increases to ∼21 percent. Contrary to recent results from the literature, we find more lopsided systems among the red early-type galaxies in the MATLAS survey compared to the mostly blue late-type hosts in ELVES. We further find that satellite galaxies at larger distances from the host, potentially recently accreted, are likely the primary contributors to the reported excess of lopsidedness. Our results set the groundwork that allows a comparison with similar systems in cosmological simulations to assess the consistency with the standard model. [ABSTRACT FROM AUTHOR]

Published

2024

2. New dwarf galaxy candidates in the sphere of influence of the Sombrero galaxy.

Author

Crosby, Ethan, Jerjen, Helmut, Müller, Oliver, Pawlowski, Marcel S, Mateo, Mario, and Lelli, Federico

Subjects

PRINCIPAL components analysis, GALAXIES, INSPECTION & review, DWARF galaxies, GALACTIC halos, GALAXY clusters

Abstract

We report the discovery of 40 new satellite dwarf galaxy candidates in the sphere of influence of the Sombrero Galaxy (M104), the most luminous galaxy in the Local Volume. Using the Subaru Hyper Suprime-Cam, we surveyed 14.4 deg2 of its surroundings, extending to the virial radius. Visual inspection of the deep images and galfit modelling yielded a galaxy sample highly complete down to Mg ∼ −9 (⁠|$L_{g}\sim 3\times 10^{5}\ \mathrm{ L}_\odot$|⁠) and spanning magnitudes −16.4 < Mg < −8 and half-light radii 50 pc < r e < 1600 pc assuming the distance of M104. These 40 new candidates, out of which 27 are group members with high confidence, double the number of potential satellites of M104 within the virial radius, placing it among the richest hosts in the Local Volume. Using a principal component analysis, we find that the entire sample of candidates is consistent with an almost circular on-sky distribution, more circular than any comparable environment found in the Illustris TNG100-1 (The Next Generation) simulation. However, the distribution of the high-probability sample is more oblate and consistent with the simulation. The cumulative satellite luminosity function is broadly consistent with analogues from the simulation, albeit it contains no bright satellite with Mg < −16.4 (⁠|$L_{g}\sim 3 \times 10^{8}\ \mathrm{ L}_\odot$|⁠), a |$2.3\, \sigma$| occurrence. Follow-up spectroscopy to confirm group membership will begin to demonstrate how these systems can act as probes of the structure and formation history of the halo of M104. [ABSTRACT FROM AUTHOR]

Published

2024

3. Measuring galaxy cluster mass profiles into the low-acceleration regime with galaxy kinematics.

Author

Li, Pengfei, Tian, Yong, Júlio, Mariana P., Pawlowski, Marcel S., Lelli, Federico, McGaugh, Stacy S., Schombert, James M., Read, Justin I., Yu, Po-Chieh, and Ko, Chung-Ming

Subjects

GALAXY clusters, KINEMATICS, HYDROSTATIC equilibrium, GALAXIES, MASS measurement, CLUSTER sampling

Abstract

We probed the dynamical mass profiles of ten galaxy clusters from the HIghest X-ray FLUx Galaxy Cluster Sample (HIFLUGCS) using galaxy kinematics. We numerically solved the spherical Jeans equation and parameterize the dynamical mass profile and the galaxy velocity anisotropy profile using two general functions to ensure that our results are not biased toward any specific model. The mass-velocity anisotropy degeneracy is ameliorated by using two "virial shape parameters" that depend on the fourth moment of velocity distribution. The resulting velocity anisotropy estimates consistently show a nearly isotropic distribution in the inner regions, with an increasing radial anisotropy toward large radii. We compared our derived dynamical masses with those calculated from X-ray gas data assuming hydrostatic equilibrium, finding that massive and rich relaxed clusters generally present consistent mass measurements, while unrelaxed or low-richness clusters have systematically larger total masses than hydrostatic masses by, on average, 50%. This might help alleviate current tensions in the measurement of σ8, but it also leads to cluster baryon fractions below the cosmic value. Finally, our approach probes accelerations as low as 10−11 m s−2, comparable to the outskirts of individual late-type galaxies. We confirm that galaxy clusters deviate from the radial acceleration relation defined by galaxies. [ABSTRACT FROM AUTHOR]

Published

2023

4. The Lopsided Distribution of Satellites of Isolated Central Galaxies.

Author

Wang, Peng, Libeskind, Noam I., Pawlowski, Marcel S., Kang, Xi, Wang, Wei, Guo, Quan, and Tempel, Elmo

Subjects

GALACTIC evolution, GALAXIES, ANGULAR distribution (Nuclear physics)

Abstract

Satellites are not randomly distributed around their central galaxies but show polar and planar structures. In this paper, we investigate the axis asymmetry or lopsidedness of satellite galaxy distributions around isolated galaxies in a hydrodynamic cosmological simulation. We find a statistically significant lopsided signal by studying the angular distribution of the satellite galaxies' projected positions around isolated central galaxies in a two-dimensional plane. The signal is dependent on galaxy mass, color, and large-scale environment. Satellites that inhabit low-mass blue hosts, or located further from the hosts, show the most lopsided signal. Galaxy systems with massive neighbors exhibit stronger lopsidedness. This satellite axis-asymmetry signal also decreases as the universe evolves. Our findings are in agreement with recent observational results and they provide a useful perspective for studying galaxy evolution, especially on the satellite accretion, internal evolution, and interaction with the cosmic large-scale structure. [ABSTRACT FROM AUTHOR]

Published

2021

5. The Alignment of Satellite Systems with Cosmic Filaments in the SDSS DR12.

Author

Wang, Peng, Libeskind, Noam I., Tempel, Elmo, Pawlowski, Marcel S., Kang, Xi, and Guo, Quan

Subjects

FIBERS, ARTIFICIAL satellites, SPINE, GALAXIES

Abstract

Galaxies, as well as their satellites, are known to form within the cosmic web, the large, multi-scale distribution of matter in the universe. It is known that the surrounding large-scale structure (LSS) can impact and influence the formation of galaxies, e.g., the spin and shape of halos or galaxies are correlated with the LSS and the correlation depends on halo mass or galaxy morphology. In this work, we use group and filament catalogs constructed from the SDSS DR12 to investigate the correlation between satellite systems and the large-scale filaments they are located in. We find that the distribution of satellites is significantly correlated with filaments, namely the major axis of the satellite systems are preferentially aligned with the spine of the closest filament. Stronger alignment signals are found for the cases where the system is far from the filament spine, while systems close to the filament spine show significantly weaker alignment. Our results suggest that satellites are accreted along filaments, which agrees with previous works. The case where the system is far from the filament spine may help us to understand how the filament forms as well as the peculiar satellite distribution in the local universe. [ABSTRACT FROM AUTHOR]

Published

2020

6. The Milky Way's disc of classical satellite galaxies in light of Gaia DR2.

Author

Pawlowski, Marcel S and Kroupa, Pavel

Subjects

*MILKY Way, *GALAXIES, *ASTROMETRY, *SATELLITE positioning, *SUPPORT groups, *PHYSICAL cosmology

Abstract

We study the correlation of orbital poles of the 11 classical satellite galaxies of the Milky Way, comparing results from previous proper motions with the independent data by Gaia DR2. Previous results on the degree of correlation and its significance are confirmed by the new data. A majority of the satellites co-orbit along the Vast Polar Structure, the plane (or disc) of satellite galaxies defined by their positions. The orbital planes of eight satellites align to <20° with a common direction, seven even orbit in the same sense. Most also share similar specific angular momenta, though their wide distribution on the sky does not support a recent group infall or satellites-of-satellites origin. The orbital pole concentration has continuously increased as more precise proper motions were measured, as expected if the underlying distribution shows true correlation that is washed out by observational uncertainties. The orbital poles of the up to seven most correlated satellites are in fact almost as concentrated as expected for the best-possible orbital alignment achievable given the satellite positions. Combining the best-available proper motions substantially increases the tension with ΛCDM cosmological expectations: <0.1 per cent of simulated satellite systems in IllustrisTNG contain seven orbital poles as closely aligned as observed. Simulated systems that simultaneously reproduce the concentration of orbital poles and the flattening of the satellite distribution have a frequency of <0.1 per cent for any number of k > 3 combined orbital poles, indicating that these results are not affected by a look-elsewhere effect. This compounds the Planes of Satellite Galaxies Problem. [ABSTRACT FROM AUTHOR]

Published

2020

7. The orientation of planes of dwarf galaxies in the quasi-linear Universe.

Author

Libeskind, Noam I, Carlesi, Edoardo, Müller, Oliver, Pawlowski, Marcel S, Hoffman, Yehuda, Pomarède, Daniel, Courtois, Helene M, Tully, R, Gottlöber, Stefan, Steinmetz, Matthias, Sorce, Jenny, and Knebe, Alexander

Subjects

DWARF galaxies, UNIVERSE, LINEAR velocity, GALAXIES, GALAXY formation, DARK matter

Abstract

To date at least 10 highly flattened planes of dwarf galaxies are claimed to have been discovered in the Local Universe. The origin of these planes of galaxies remains unknown. One suggestion is that they are related to the large-scale structure of the cosmic web. A recent study found that the normal of a number of these dwarf galaxy planes is very closely aligned with the eigenvector of the shear tensor corresponding to the direction of greatest collapse obtained by reconstructing the full velocity field in the linear regime. Here we extend that work by both considering an additional 5 planes beyond the five examined previously and examining the alignment with respect to the quasi-linear field, a more sophisticated reconstruction, which is a better approximation on smaller (quasi-linear) scales. Our analysis recovers the previous result while not finding a significantly tight alignment with the additional five planes. However, the additional five plane normals also do not appear to be randomly oriented. We conclude that this could be due either to the normals of the new planes being poorly defined and described; the quasi-linear field at those locations being poorly constrained; or different formation mechanisms for the orientation of planes of dwarf galaxies. [ABSTRACT FROM AUTHOR]

Published

2019

8. Phat ELVIS: The inevitable effect of the Milky Way's disc on its dark matter subhaloes.

Author

Kelley, Tyler, Bullock, James S, Garrison-Kimmel, Shea, Boylan-Kolchin, Michael, Pawlowski, Marcel S, and Graus, Andrew S

Subjects

MILKY Way, DARK matter, DWARF galaxies, GALAXIES

Abstract

We introduce an extension of the ELVIS project to account for the effects of the Milky Way galaxy on its subhalo population. Our simulation suite, Phat ELVIS, consists of 12 high-resolution cosmological dark matter-only (DMO) zoom simulations of Milky Way-size ΛCDM haloes [ M v = (0.7−2) × 1012 M⊙] along with 12 re-runs with embedded galaxy potentials grown to match the observed Milky Way disc and bulge today. The central galaxy potential destroys subhalos on orbits with small pericentres in every halo, regardless of the ratio of galaxy mass to halo mass. This has several important implications. (1) Most of the Disc runs have no subhaloes larger than V max = 4.5 km s−1 within 20 kpc and a significant lack of substructure going back ∼8 Gyr, suggesting that local stream-heating signals from dark substructure will be rare. (2) The pericentre distributions of Milky Way satellites derived from Gaia data are remarkably similar to the pericentre distributions of subhaloes in the Disc runs, while the DMO runs drastically overpredict galaxies with pericentres smaller than 20 kpc. (3) The enhanced destruction produces a tension opposite to that of the classic 'missing satellites' problem: in order to account for ultra-faint galaxies known within 30 kpc of the Galaxy, we must populate haloes with V peak ≃ 7 km s−1 (M  ≃ 3 × 107 M⊙ at infall), well below the atomic cooling limit of |$V_\mathrm{peak}\simeq 16 \,{\rm km} \, {\rm s}^{-1}$| (M  ≃ 5 × 108M⊙ at infall). (4) If such tiny haloes do host ultra-faint dwarfs, this implies the existence of ∼1000 satellite galaxies within 300 kpc of the Milky Way. [ABSTRACT FROM AUTHOR]

Published

2019

9. The planes of satellite galaxies problem, suggested solutions, and open questions.

Author

Pawlowski, Marcel S.

Subjects

*GALAXIES, *MILKY Way, *DISTRIBUTION of stars, *SOLAR system, *GALACTIC coordinates

Abstract

Satellite galaxies of the Milky Way and of the Andromeda galaxy have been found to preferentially align in significantly flattened planes of satellite galaxies, and available velocity measurements are indicative of a preference of satellites in those structures to co-orbit. There is an increasing evidence that such kinematically correlated satellite planes are also present around more distant hosts. Detailed comparisons show that similarly anisotropic phase-space distributions of sub-halos are exceedingly rare in cosmological simulations based on the ΛCDM paradigm. Analogs to the observed systems have frequencies of ≤0.5% in such simulations. In contrast to other small-scale problems, the satellite planes issue is not strongly affected by baryonic processes because the distribution of sub-halos on scales of hundreds of kpc is dominated by gravitational effects. This makes the satellite planes one of the most serious small-scale problems for ΛCDM. This review summarizes the observational evidence for planes of satellite galaxies in the Local Group and beyond, and provides an overview of how they compare to cosmological simulations. It also discusses scenarios which aim at explaining the coherence of satellite positions and orbits, and why they all are currently unable to satisfactorily resolve the issue. [ABSTRACT FROM AUTHOR]

Published

2018

10. A whirling plane of satellite galaxies around Centaurus A challenges cold dark matter cosmology.

Author

Müller, Oliver, Pawlowski, Marcel S., Jerjen, Helmut, and Lelli, Federico

Subjects

*MILKY Way, *ANDROMEDA Galaxy, *NATURAL satellites, *DWARF galaxies, *GALAXIES

Abstract

The Milky Way and Andromeda galaxies are each surrounded by a thin plane of satellite dwarf galaxies that may be corotating. Cosmological simulations predict that most satellite galaxy systems are close to isotropic with random motions, so those two wellstudied systems are often interpreted as rare statistical outliers. We test this assumption using the kinematics of satellite galaxies around the Centaurus A galaxy. Our statistical analysis reveals evidence for corotation in a narrow plane: Of the 16 Centaurus A satellites with kinematic data, 14 follow a coherent velocity pattern aligned with the long axis of their spatial distribution. In standard cosmological simulations, <0.5% of Centaurus A–like systems show such behavior. Corotating satellite systems may be common in the universe, challenging small-scale structure formation in the prevailing cosmological paradigm. [ABSTRACT FROM AUTHOR]

Published

2018

11. Phase-Space Correlations among Systems of Satellite Galaxies.

Author

Pawlowski, Marcel S.

Subjects

GALAXY clusters, GALAXIES, MILKY Way, PHYSICAL cosmology, DWARF galaxies

Abstract

Driven by the increasingly complete observational knowledge of systems of satellite galaxies, mutual spatial alignments and relations in velocities among satellites belonging to a common host have become a productive field of research. Numerous studies have investigated different types of such phase-space correlations and were met with varying degrees of attention by the community. The Planes of Satellite Galaxies issue is maybe the best-known example, with a rich field of research literature and an ongoing, controversial debate on how much of a challenge it poses to the Λ CDM model of cosmology. Another type of correlation, the apparent excess of close pairs of dwarf galaxies, has received considerably less attention despite its reported tension with Λ CDM expectations. With the fast expansion of proper motion measurements in recent years, largely driven by the Gaia mission, other peculiar phase-space correlations have been uncovered among the satellites of the Milky Way. Examples are the apparent tangential velocity excess of satellites compared to cosmological expectations, and the unexpected preference of satellites to be close to their pericenters. At the same time, other kinds of correlations have been found to be more in line with cosmological expectations—specifically, lopsided satellite galaxy systems and the accretion of groups of satellite galaxies. The latter has mostly been studied in cosmological simulations thus far, but it offers the potential to address some of the other issues by providing a way to produce correlations among the orbits of a group's satellite galaxy members. This review is the first to provide an introduction to the highly active field of phase-space correlations among satellite galaxy systems. The emphasis is on summarizing existing, recent research and highlighting interdependencies between the different, currently almost exclusively individually considered types of correlations. Future prospects in light of upcoming observational facilities and our ever-expanding knowledge of satellite galaxy systems beyond the Local Group are also briefly discussed. [ABSTRACT FROM AUTHOR]

Published

2021

12. THE VAST POLAR STRUCTURE OF THE MILKY WAY ATTAINS NEW MEMBERS.

Author

Pawlowski, Marcel S. and Kroupa, Pavel

Subjects

*GALAXIES, *GLOBULAR clusters, *MILKY Way, *ANISOTROPY, *DWARF galaxies

Abstract

The satellite galaxies of the Milky Way (MW) align with and preferentially orbit in a vast polar structure (VPOS), which also contains globular clusters (GCs) and stellar and gaseous streams. Similar alignments have been discovered around several other host galaxies. We test whether recently discovered objects in the MW halo, the satellite galaxy/GC transition object named PSO J174.0675-10.8774 or Crater and three stellar streams, are part of the VPOS. Crater is situated close to the VPOS. Incorporating the new object in the VPOS-plane fit slightly improves the alignment of the plane with other features such as the Magellanic stream and the average orbital plane of the satellites co-orbiting in the VPOS. We predict Crater's proper motion by assuming that it, too, orbits in the VPOS. One of the three streams aligns well with the VPOS. Surprisingly, it appears to lie in the exact same orbital plane as the Palomar 5 stream and shares its distance, suggesting a direct connection between the two. The stream also crosses close to the Fornax dwarf galaxy and is oriented approximately along the galaxy's direction of motion. The two other streams cannot align closely with the VPOS because they were discovered in the direction of M31/M33, which is outside of the satellite structure. The VPOS thus attains two new members. This further emphasizes that the highly anisotropic and correlated distribution of satellite objects requires an explanation beyond the suggestion that the MW satellite system is an extreme statistical outlier of a ΛCDM sub-halo system. [ABSTRACT FROM AUTHOR]

Published

2014

13. Radial Acceleration Relation of Λ CDM Satellite Galaxies.

Author

Garaldi, Enrico, Romano-Díaz, Emilio, Porciani, Cristiano, and Pawlowski, Marcel S.

Subjects

*CENTRIPETAL acceleration, *METAPHYSICAL cosmology, *GALAXIES

Abstract

The radial acceleration measured in bright galaxies tightly correlates with that generated by the observed distribution of baryons, a phenomenon known as the radial acceleration relation (RAR). Dwarf spheroidal satellite galaxies have been recently found to depart from the extrapolation of the RAR measured for more massive objects but with a substantially larger scatter. If confirmed by new data, this result provides a powerful test of the theory of gravity at low accelerations that requires robust theoretical predictions. By using high-resolution hydrodynamical simulations, we show that, within the standard model of cosmology (Λ CDM), satellite galaxies are expected to follow the same RAR as brighter systems but with a much larger scatter which does not correlate with the physical properties of the galaxies. In the simulations, the RAR evolves mildly with redshift. Moreover, the acceleration due to the gravitational field of the host has no effect on the RAR. This is in contrast with the external field effect in modified Newtonian dynamics (MOND) which causes galaxies in strong external fields to deviate from the RAR. This difference between Λ CDM and MOND offers a possible way to discriminate between them. [ABSTRACT FROM AUTHOR]

Published

2018