On wave dark matter in spiral and barred galaxies

Abstract Boxy, peanut– or X–shaped “bulges” are observed in a large fraction of barred galaxies viewed in, or close to, edge-on projection, as well as in the Milky Way. They are the product of dynamical instabilities occurring in stellar bars, which cause the latter to buckle and thicken vertically. Recent studies have found nearby galaxies that harbour two such features arising at different radial scales, in a nested configuration. In this paper we explore the formation of such double peanuts, using a collisionless N–body simulation of a pure disc evolving in isolation within a live dark matter halo, which we analyse in a completely analogous way to observations of real galaxies. In the simulation we find a stable double configuration consisting of two X/peanut structures associated to the same galactic bar – rotating with the same pattern speed – but with different morphology, formation time, and evolution. The inner, conventional peanut-shaped structure forms early via the buckling of the bar, and experiences little evolution once it stabilises. This feature is consistent in terms of size, strength and morphology, with peanut structures observed in nearby galaxies. The outer structure, however, displays a strong X, or “bow-tie”, morphology. It forms just after the inner peanut, and gradually extends in time (within 1 to 1.5 Gyr) to almost the end of the bar, a radial scale where ansae occur. We conclude that, although both structures form, and are dynamically coupled to, the same bar, they are supported by inherently different mechanisms.

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Dark matter bar evolution in triaxial spinning haloes

Proceedings of the International Astronomical Union ◽

10.1017/s1743921320001519 ◽

2020 ◽

Vol 15 (S359) ◽

pp. 446-447

Author(s):

Daniel A. Marostica ◽

Rubens E. G. Machado

Keyword(s):

Dark Matter ◽

The Other ◽

Barred Galaxies ◽

Other Hand ◽

Dynamical Instabilities

AbstractDark matter bars are structures that may form inside dark matter haloes of barred galaxies. Haloes can depart from sphericity and also be subject to some spin. The latter is known to have profound impacts on the evolution of both stellar and DM bars, such as stronger dynamical instabilities, more violent vertical bucklings and dissolution or impairment of stellar bar growth. On the other hand, dark matter bars of spherical haloes become initially stronger in the presence of spin. In this study, we add spin to triaxial halos in order to quantify and compare the strength of their bars. Using N-body simulations, we find that spin accelerates main instabilities and strengthens the halo bars, although their final strength depends only on triaxiality. The most triaxial halo barely forms a halo bar, showing that flattening opposes to DM bar strengthening and indicating that there is a limit on how flattened the parent structure can be.

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Jeans analysis for dwarf spheroidal galaxies in wave dark matter

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/stx449 ◽

2017 ◽

Vol 468 (2) ◽

pp. 1338-1348 ◽

Cited By ~ 42

Author(s):

Shu-Rong Chen ◽

Hsi-Yu Schive ◽

Tzihong Chiueh

Keyword(s):

Dark Matter ◽

Dwarf Spheroidal Galaxies ◽

Wave Dark Matter ◽

Spheroidal Galaxies

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The Dark Matter Content of Barred Spiral Galaxies

Symposium - International Astronomical Union ◽

10.1017/s007418090018338x ◽

2004 ◽

Vol 220 ◽

pp. 277-278

Author(s):

Glen Petitpas ◽

Mousumi Das ◽

Peter Teuben ◽

Stuart Vogel

Keyword(s):

Dark Matter ◽

Spiral Galaxies ◽

Velocity Fields ◽

Matter Content ◽

Two Dimensional ◽

Disk Model ◽

Barred Galaxies ◽

Preliminary Results ◽

Nearby Galaxies ◽

Barred Spiral Galaxies

Two-dimensional velocity fields have been used to determine the dark matter properties of a sample of barred galaxies taken from the BIMA Survey of Nearby Galaxies (SONG). Preliminary results indicate that the maximal disk model is not appropriate in several galaxies in our sample, but higher resolution results will be needed to confirm this.

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Constraints from Dynamical Friction on the Dark Matter Content of Barred Galaxies

The Astrophysical Journal ◽

10.1086/317148 ◽

2000 ◽

Vol 543 (2) ◽

pp. 704-721 ◽

Cited By ~ 342

Author(s):

Victor P. Debattista ◽

J. A. Sellwood

Keyword(s):

Dark Matter ◽

Matter Content ◽

Dynamical Friction ◽

Barred Galaxies

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Black Hole Window intop-Wave Dark Matter Annihilation

Physical Review Letters ◽

10.1103/physrevlett.115.231302 ◽

2015 ◽

Vol 115 (23) ◽

Cited By ~ 15

Author(s):

Jessie Shelton ◽

Stuart L. Shapiro ◽

Brian D. Fields

Keyword(s):

Black Hole ◽

Dark Matter ◽

Dark Matter Annihilation ◽

Wave Dark Matter

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An interesting case of the formation and evolution of a barred galaxy in the cosmological context

Astronomy and Astrophysics ◽

10.1051/0004-6361/202039425 ◽

2020 ◽

Vol 642 ◽

pp. L12

Author(s):

Ewa L. Łokas

Keyword(s):

Dark Matter ◽

Galaxy Formation ◽

Cosmic Time ◽

Galaxy Cluster ◽

Interesting Case ◽

Massive Galaxies ◽

Barred Galaxies ◽

Tidal Interactions ◽

The Galaxy ◽

Formation And Evolution

Elongated, bar-like galaxies without a significant disk component, with little rotation support and no gas, often form as a result of tidal interactions with a galaxy cluster, as was recently demonstrated using the IllustrisTNG-100 simulation. Galaxies that exhibit similar properties are, however, also found to be infalling into the cluster for the first time. We use the same simulation to study in detail the history of such a galaxy over cosmic time in order to determine its origin. The bar appears to be triggered at t = 6.8 Gyr by the combined effect of the last significant merger with a subhalo and the first passage of another dwarf satellite, both ten times less massive than the galaxy. The satellites deposit all their gas in the galaxy, contributing to its third and last star-formation episode, which perturbs the disk and may also contribute to the formation of the bar. The galaxy then starts to lose its gas and dark matter due to its passage near a group of more massive galaxies. The strongest interaction involves a galaxy 22 times more massive, leaving the barred galaxy with no gas and half of its maximum dark matter mass. During this time, the bar grows steadily, seemingly unaffected by the interactions, although they may have aided its growth by stripping the gas. The studied galaxy, together with two other similar objects briefly discussed in this Letter, suggest the existence of a new class of early-type barred galaxies and thereby demonstrate the importance of interactions in galaxy formation and evolution.

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Wave Dark Matter

Annual Review of Astronomy and Astrophysics ◽

10.1146/annurev-astro-120920-010024 ◽

2021 ◽

Vol 59 (1) ◽

pp. 247-289

Author(s):

Lam Hui

Keyword(s):

Dark Matter ◽

Gravitational Lensing ◽

Particle Physics ◽

Density Fluctuations ◽

Dark Matter Candidate ◽

Order Unity ◽

Wave Interference ◽

Wave Nature ◽

Tidal Streams ◽

Wave Dark Matter

We review the physics and phenomenology of wave dark matter: a bosonic dark matter candidate lighter than about 30 eV. Such particles have a de Broglie wavelength exceeding the average interparticle separation in a galaxy like the Milky Way and are, thus, well described as a set of classical waves. We outline the particle physics motivations for such particles, including the quantum chromodynamics axion as well as ultralight axion-like particles such as fuzzy dark matter. The wave nature of the dark matter implies a rich phenomenology: ▪ Wave interference gives rise to order unity density fluctuations on de Broglie scale in halos. One manifestation is vortices where the density vanishes and around which the velocity circulates. There is one vortex ring per de Broglie volume on average. ▪ For sufficiently low masses, soliton condensation occurs at centers of halos. The soliton oscillates and undergoes random walks, which is another manifestation of wave interference. The halo and subhalo abundance is expected to be suppressed at small masses, but the precise prediction from numerical wave simulations remains to be determined. ▪ For ultralight ∼10−22 eV dark matter, the wave interference substructures can be probed by tidal streams or gravitational lensing. The signal can be distinguished from that due to subhalos by the dependence on stream orbital radius or image separation. ▪ Axion detection experiments are sensitive to interference substructures for wave dark matter that is moderately light. The stochastic nature of the waves affects the interpretation of experimental constraints and motivates the measurement of correlation functions. Current constraints and open questions, covering detection experiments and cosmological, galactic, and black hole observations, are discussed.

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Dark matter in the inner parts of barred galaxies

10.22323/1.014.0047 ◽

2004 ◽

Author(s):

Isabel Perez Martin

Keyword(s):

Dark Matter ◽

Barred Galaxies ◽

Inner Parts

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Fast galaxy bars continue to challenge standard cosmology

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/stab2553 ◽

2021 ◽

Vol 508 (1) ◽

pp. 926-939

Author(s):

Mahmood Roshan ◽

Neda Ghafourian ◽

Tahere Kashfi ◽

Indranil Banik ◽

Moritz Haslbauer ◽

...

Keyword(s):

Dark Matter ◽

Cold Dark Matter ◽

Dark Matter Halo ◽

Dynamical Friction ◽

Statistical Population ◽

Barred Galaxies ◽

Corotation Radius ◽

Pattern Speeds ◽

Hydrodynamical Simulations ◽

Disc Galaxies

ABSTRACT Many observed disc galaxies harbour a central bar. In the standard cosmological paradigm, galactic bars should be slowed down by dynamical friction from the dark matter halo. This friction depends on the galaxy’s physical properties in a complex way, making it impossible to formulate analytically. Fortunately, cosmological hydrodynamical simulations provide an excellent statistical population of galaxies, letting us quantify how simulated galactic bars evolve within dark matter haloes. We measure bar strengths, lengths, and pattern speeds in barred galaxies in state-of-the-art cosmological hydrodynamical simulations of the IllustrisTNG and EAGLE projects, using techniques similar to those used observationally. We then compare our results with the largest available observational sample at redshift z = 0. We show that the tension between these simulations and observations in the ratio of corotation radius to bar length is 12.62σ (TNG50), 13.56σ (TNG100), 2.94σ (EAGLE50), and 9.69σ (EAGLE100), revealing for the first time that the significant tension reported previously persists in the recently released TNG50. The lower statistical tension in EAGLE50 is actually caused by it only having five galaxies suitable for our analysis, but all four simulations give similar statistics for the bar pattern speed distribution. In addition, the fraction of disc galaxies with bars is similar between TNG50 and TNG100, though somewhat above EAGLE100. The simulated bar fraction and its trend with stellar mass both differ greatly from observations. These dramatic disagreements cast serious doubt on whether galaxies actually have massive cold dark matter haloes, with their associated dynamical friction acting on galactic bars.

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