Characterization of galactic bars from 3.6<i>μ</i>m S<sup>4</sup>G imaging

Díaz-García, Simón; Salo, H.; Laurikainen, Eija; Herrera-Endoqui, M.

doi:10.1051/0004-6361/201526161

Cited by 135 publications

(219 citation statements)

References 172 publications

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“…Our halo model is chosen so that at h 2.2 r , the disk accounts for 65% of the total radial force. This corresponds to the typical value estimated for an MW mass galaxy in Díaz-García et al (2016b), obtained by combining the gravitational field calculated from the 3.6 μm images using the NIRQB code (Salo et al 1999;Laurikainen & Salo 2002), with the rotation amplitudes obtained from the HI-kinematics (Courtois et al 2009 , which correspond to the maximum disk contribution to circular velocity ∼170 km s −1 (total circular velocity ∼215 km s −1 ; see Figure 1). Our standard value for gravity softening is  = h 0.01 r , and the time step is~-10 2 time units; in physical units one time unit corresponds to ∼10 Myr.…”

Section: Simulationssupporting

confidence: 73%

Boxy/Peanut/X-shaped Bulges: Steep Inner Rotation Curve Leads to Barlens Face-on Morphology

Salo

Laurikainen

2017

ApJ

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We use stellar dynamical bulge/disk/halo simulations to study whether barlenses (lens-like structures embedded in the narrow bar component) are only the face-on counterparts of Boxy/Peanut/X-shapes (B/P/X) seen in edge-on bars, or if some additional physical parameter affects that morphology. A range of bulge-to-disk mass and size ratios are explored: our nominal parameters (, disk comprisingtwo-thirds of total force at h 2.2 r ) correspond to typical Milky Way mass galaxies. In all models, a bar with pronounced B/P/X forms in a few Gyr, visiblein the edge-on view. However, the pure barlens morphology forms only in models with sufficiently steep inner rotation curves,, achieved when including a small classical bulge with  B D 0.02 and  r h 0.1 r eff . For shallower slopes, the central structure still resembles a barlens, but shows a clear X signature even in low inclinations. A similar result holds for bulge-less simulations, where the central slope is modified by changing the halo concentration. The predicted sensitivity on the inner rotation curve is consistent with the slopes that are estimated from gravitational potentials calculated from the 3.6 μm images, for the observed barlens and X-shaped galaxies in the Spitzer Survey of Stellar Structure in Galaxies (S 4 G). For inclinations <60°t he galaxies with barlenses have on average twice steeper inner rotation curves than galaxies with X shapes: the limiting slope is ∼250 km s −1 kpc −1 . Among barred galaxies, those with barlenses have both the strongest bars and the largest relative excess of inner surface density, both in barlens regions ( h 0.5 r ) and near the center ( h 0.1 r ); this provides evidence for bar-driven secular evolution in galaxies.

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Section: Simulationssupporting

confidence: 73%

Boxy/Peanut/X-shaped Bulges: Steep Inner Rotation Curve Leads to Barlens Face-on Morphology

Salo

Laurikainen

2017

ApJ

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“…When they calculated the bar strength from the torque maps, they found a steady growth along the Hubble sequence. The same method was employed by Díaz-García et al (2016) with a large sample of ∼600 galaxies, finding a similar result. Similarly, Seidel et al (2015) used torques to estimate the bar strength and also found this growth of the bar strength from early to intermediate type of galaxies, with a sample of 16 galaxies.…”

Section: Variation Of Bar Parameters With the Morphological Type Of Tmentioning

confidence: 53%

“…This technique was initially applied to real galaxies in Wozniak & Pierce (1991) and in Wozniak et al (1995) based on the technique described by Jedrzejewski (1987). This method has been extensively used on real galaxies (Laine et al 2002;Erwin & Sparke 2003;Sheth et al 2003;Erwin 2004Erwin , 2005 Aguerri et al 2009;Díaz-García et al 2016). A variation of this technique has also been used to determine the bar length in simulated galaxies (Athanassoula et al 1990;Villa-Vargas et al 2009Athanassoula 2014).…”

Section: Introductionmentioning

confidence: 99%

“…(ii) The bar strength can be defined from the Fourier decompositions of the galaxy image (Ohta et al 1990;Marquez et al 1996;Laurikainen et al , 2005Athanassoula 2003;Athanassoula et al 2013;Díaz-García et al 2016;Martínez-Valpuesta et al 2017). (iii) Finally, the bar strength can be determined from the torque of the bar measured from the gravitational potential inferred from the infrared image (Combes & Sanders 1981;Quillen et al 1994;Buta & Block 2001;Berentzen et al 2007;Tiret & Combes 2008;Salo et al 2010;Díaz-García et al 2016).…”

Section: Introductionmentioning

confidence: 99%

“…(iii) Finally, the bar strength can be determined from the torque of the bar measured from the gravitational potential inferred from the infrared image (Combes & Sanders 1981;Quillen et al 1994;Buta & Block 2001;Berentzen et al 2007;Tiret & Combes 2008;Salo et al 2010;Díaz-García et al 2016).…”

Section: Introductionmentioning

confidence: 99%

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Kinematic Clues to Bar Evolution for Galaxies in the Local Universe: Why the Fastest Rotating Bars are Rotating Most Slowly

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Beckman

Martínez-Valpuesta

et al. 2017

ApJ

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We have used Spitzer images of a sample of 68 barred spiral galaxies in the local universe to make systematic measurements of bar length and bar strength. We combine these with precise determinations of the corotation radii associated with the bars, taken from our previous study, which used the phase change from radial inflow to radial outflow of gas at corotation, based on high-resolution two-dimensional velocity fields in Hα taken with a FabryPérot spectrometer. After presenting the histograms of the derived bar parameters, we study their dependence on the galaxy morphological type and on the total stellar mass of the host galaxy, and then produce a set of parametric plots. These include the bar pattern speed versus bar length, the pattern speed normalized with the characteristic pattern speed of the outer disk versus the bar strength, and the normalized pattern speed versus , the ratio of corotation radius to bar length. To provide guidelines for our interpretation, we used recently published simulations, including disk and dark matter halo components. Our most striking conclusion is that bars with values of  < 1.4, previously considered dynamically fast rotators, can be among the slowest rotators both in absolute terms and when their pattern speeds are normalized. The simulations confirm that this is because as the bars are braked, they can grow longer more quickly than the outward drift of the corotation radius. We conclude that dark matter halos have indeed slowed down the rotation of bars on Gyr timescales.

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The halo-to-stellar mass ratio in the S⁴G

2016

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We use 3.6 μm photometry for 1154 disk galaxies (i < 65°) in the S4G (Sheth et al. 2010). We obtain the average stellar component of the circular velocity (Vdisk) and the mean (dark matter) halo-to-stellar mass ratio (Mhalo/M*) inside the optical radius (Ropt) in bins of total stellar mass (M*, from Muñoz-Mateos et al. 2015), providing observational constraints for galaxy formation models to be tested against. We find the Mhalo/M* − M* relation in good agreement with the best-fit model at z ≈ 0 in ΛCDM cosmological simulations (e.g. Moster 2010), assuming that the dark matter halo within Ropt comprises a constant fraction (~ 4%) of its total mass.

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Characterization of galactic bars from 3.6μm S⁴G imaging

Cited by 135 publications

References 172 publications

Boxy/Peanut/X-shaped Bulges: Steep Inner Rotation Curve Leads to Barlens Face-on Morphology

Boxy/Peanut/X-shaped Bulges: Steep Inner Rotation Curve Leads to Barlens Face-on Morphology

Kinematic Clues to Bar Evolution for Galaxies in the Local Universe: Why the Fastest Rotating Bars are Rotating Most Slowly

The halo-to-stellar mass ratio in the S⁴G

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Characterization of galactic bars from 3.6μm S4G imaging

Cited by 135 publications

References 172 publications

Boxy/Peanut/X-shaped Bulges: Steep Inner Rotation Curve Leads to Barlens Face-on Morphology

Boxy/Peanut/X-shaped Bulges: Steep Inner Rotation Curve Leads to Barlens Face-on Morphology

Kinematic Clues to Bar Evolution for Galaxies in the Local Universe: Why the Fastest Rotating Bars are Rotating Most Slowly

The halo-to-stellar mass ratio in the S4G

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Characterization of galactic bars from 3.6μm S⁴G imaging

The halo-to-stellar mass ratio in the S⁴G