A parametric description of the 3D structure of the Galactic bar/bulge using the VVV survey

Simion, Iulia T.; Belokurov, V.; Irwin, M. J.; Koposov, S. E.; González-Fernández, C.; Robin, A. C.; Shen, Juntai; Li, Zhaoyu

doi:10.1093/mnras/stx1832

Cited by 61 publications

(96 citation statements)

References 84 publications

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“…In small fields of 0.2 deg × 0.2 deg across the VVV bulge footprint, the bulge giants (both red giant branch and red clump) were selected in a unextincted colour-magnitude box of 0.4 < (J − K s ) 0 < 1 and 11.5 < K s0 < 14.5 using a two-dimensional extinction map from the method of Gonzalez et al (2011). First, the density in each field was measured assuming a luminosity function (taken from Simion et al 2017) and accounting for incompleteness, and then the density distribution was used to extract the first two moments of the transverse velocity distributions as a function of distance by probabilistically considering the possible velocities for each star given its K s0 magnitude. Here we utilise the mean longitudinal transverse velocities with location v ( , b, s) and the density field ρ( , b, s) computed on a grid in log(distance), and b.…”

Section: Application To Datamentioning

confidence: 99%

The pattern speed of the Milky Way bar from transverse velocities

Sanders

Smith

Evans

2019

Monthly Notices of the Royal Astronomical Society

130

102

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We use the continuity equation to derive a method for measuring the pattern speed of the Milky Way's bar/bulge from proper motion data. The method has minimal assumptions but requires complete coverage of the non-axisymmetric component in two of the three Galactic coordinates. We apply our method to the proper motion data from a combination of Gaia DR2 and VISTA Variables in the Via Lactea (VVV) to measure the pattern speed of the bar as Ω p = (41 ± 3) km s −1 kpc −1 (where the error is statistical). This puts the corotation radius at (5.7 ± 0.4) kpc, under the assumptions of the standard peculiar motion of the Sun and the absence of non-axisymmetric streaming in the Solar neighbourhood. The obtained result uses only data on the near-side of the bar which produces consistent measurements of the distance and velocity of the centre of the Galaxy. Addition of the data on the far-side of the bar pulls the pattern speed down to Ω p = (31 ± 1) km s −1 kpc −1 but requires a lower transverse velocity for the Galactic centre than observed. This suggests systematics of 5 − 10 km s −1 kpc −1 dominate the uncertainty. We demonstrate using a dynamically-formed bar/bulge simulation that even with the limited field of view of the VVV survey our method robustly recovers the pattern speed.

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Section: Application To Datamentioning

confidence: 99%

The pattern speed of the Milky Way bar from transverse velocities

Sanders

Smith

Evans

2019

Monthly Notices of the Royal Astronomical Society

130

102

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“…Red clump giants have been used as a tracer of the structure of the bulge in numerous studies (Stanek et al 1997;Saito et al 2011;Wegg & Gerhard 2013;Simion et al 2017) due to their standard candle nature. They appear as a clear peak in bulge colourmagnitude diagrams, lying at (J − K s ) 0 ≈ 0.6 and between K s0 ≈ 12 and K s0 ≈ 14 depending on Galactic longitude (subscript 0 denotes unextincted -we describe extinction correction in the following section).…”

Section: Selectionmentioning

confidence: 99%

“…metallicity) are unimportant so we use a single luminosity function for both components. The luminosity function p(M K s ) is adopted from Simion et al (2017) composed of three Gaussian peaks for the AGB, RGB and RC bumps along with a background RGB exponential: Simion et al (2017) sets a g = a g0 = 0.642. Simion et al (2017) allowed the mean magnitude of the red clump to vary in their modelling.…”

Section: Luminosity Functionmentioning

confidence: 99%

“…The luminosity function p(M K s ) is adopted from Simion et al (2017) composed of three Gaussian peaks for the AGB, RGB and RC bumps along with a background RGB exponential: Simion et al (2017) sets a g = a g0 = 0.642. Simion et al (2017) allowed the mean magnitude of the red clump to vary in their modelling. Requiring a Galactic centre distance of 8 kpc, Simion et al (2017) found M K, RC = −1.63 mag consistent with the solar neighbourhood result of M K, RC = −1.61 mag (Alves 2000;Hawkins et al 2017).…”

Section: Luminosity Functionmentioning

confidence: 99%

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Transverse kinematics of the Galactic bar-bulge from VVV and Gaia

Sanders

Smith

Evans

et al. 2019

Monthly Notices of the Royal Astronomical Society

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We analyse the kinematics of the Galactic bar-bulge using proper motions from the ESO public survey Vista Variables in the Via Lactea (VVV) and the second Gaia data release. Gaia has provided some of the first absolute proper motions within the bulge and the near-infrared VVV multi-epoch catalogue complements Gaia in highly-extincted low-latitude regions. We discuss the relative-to-absolute calibration of the VVV proper motions using Gaia. Along lines of sight spanning −10 < / deg < 10 and −10 < b/ deg < 5, we probabilistically model the density and velocity distributions as a function of distance of ∼ 45 million stars. The transverse velocities confirm the rotation signature of the bar seen in spectroscopic surveys. The differential rotation between the double peaks of the magnitude distribution confirms the X-shaped nature of the bar-bulge. Both transverse velocity components increase smoothly along the near-side of the bar towards the Galactic centre, peak at the Galactic centre and decline on the far-side. The anisotropy is σ /σ b ≈ 1.1 − 1.3 within the bulk of the bar, reducing to 0.9 − 1.1 when rotational broadening is accounted for, and exhibits a clear Xshaped signature. The vertex deviation in and b is significant | ρ b | 0.2, greater on the nearside of the bar and produces a quadrupole signature across the bulge indicating approximate radial alignment. We have re-constructed the 3D kinematics from the assumption of triaxiality, finding good agreement with spectroscopic survey results. In the co-rotating frame, we find evidence of bar-supporting x1 orbits and tangential bias in the in-plane dispersion field.

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“…There is a lot of evidence that our Galaxy includes a bar. Infrared observations of the inner Galactic plane (Dwek et al 1995;Benjamin et al 2005;Cabrera-Lavers et al 2007;Churchwell et al 2009;González-Fernández et al 2012), gas kinematics in the inner Galaxy (Pohl et al 2008;Gerhard 2011), X-shaped distribution of red giants in the central region derived from BRAVA, WISE and VVV data (Li & Shen 2012;Ness & Lang 2016;Simion et al 2017) confirm the presence of the bar in the Galaxy. The estimates of the length of the bar major semi-axis lie in the range 3-5 kpc which corresponds to the bar angular velocity 40-70 km s −1 .…”

Section: Introductionmentioning

confidence: 95%

Galactic resonance rings: modelling of motions in the wide solar neighbourhood

Melnik

2019

Monthly Notices of the Royal Astronomical Society

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Models of the Galaxy with analytical Ferrers bars can reproduce the residual velocities of OB-associations in the Sagittarius, Perseus and Local System stellar-gas complexes located within 3 kpc solar neighborhood. Ferrers ellipsoids with density distribution defined by power indices n = 1 and 2 are considered. The success in the reproduction of the velocity in the Local System is due to the large velocity dispersion which weakens the resonance effects by producing smaller systematic motions. Model galaxies form nuclear, inner and outer resonance rings R 1 and R 2 . The outer rings R 2 manage to catch twice more particles than the rings R 1 . The outer Lindblad resonance of the bar (OLR) is located 0.4 kpc beyond the solar circle, R OLR = R 0 + 0.4 kpc, corresponding to the bar angular velocity of Ω b = 50 km s −1 kpc −1 . The solar position angle with respect to the bar, θ b , providing the agreement between model and observed velocities is 40-52 • . Unfortunately, models considered cannot reproduce the residual velocities in the Carina and Cygnus stellar-gas complexes. The redistribution of the specific angular momentum, L, is found near the Lindblad resonances of the bar (ILR and OLR): the average value of L increases (decreases) at the radii a bit smaller (larger) than those of the resonances that can be connected with the existence of two types of periodic orbits elongated perpendicular to each other there.

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A parametric description of the 3D structure of the Galactic bar/bulge using the VVV survey

Cited by 61 publications

References 84 publications

The pattern speed of the Milky Way bar from transverse velocities

The pattern speed of the Milky Way bar from transverse velocities

Transverse kinematics of the Galactic bar-bulge from VVV and Gaia

Galactic resonance rings: modelling of motions in the wide solar neighbourhood

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