HOME   deutsch Contact    Sitemap    Impressum   INTRANET     

link to MPE home
link to Max Planck Society

  für extraterrestrische Physik

(Max Planck Institute for Extraterrestrial Physics)

link MPE
link Institute
link News
link Research Areas
link Projects
link Collaborations
link Public Outreach
link Publications
link Links
link Astronomy
    linkMPE   linkNews   pointer2012-02-15  
MPE News February 15, 2012

The Milky Way - tomography of a barred spiral galaxy

Our home galaxy, the Milky Way, is still enigmatic. Scientists at the Max Planck Institute for Extraterrestrial Physics have now modelled the components in its interior, linking new observations of projected star counts with the three-dimensional distribution of the stars: in the middle of an elongated bulge, extending some 10 000 light-years across the Milky Way centre, there is a dense, almost round distribution of stars about 4000 light-years in diameter. Further out the bulge transforms into a bar reaching out to about 15 000 light years and interacting with the Milky Way's spiral arms. In the model, these components form naturally during the intrinsic development of a disk galaxy and consist of stars made originally in the disk. Our Milky Way therefore could have started out as a pure disk galaxy.

galaxy NGC 1073
Figure 1: The galaxy NGC 1073 is a spiral galaxy with a bar-shaped bulge in the middle. If we could observe our Milky Way "from above" it would look very similar.
Credit: NASA & ESA
Our Milky Way, like many other spiral galaxies, consists of a disk with spiral arms containing relatively young stars, and an elongated "bulge" in the central region with predominantly old stars. In addition, the Milky Way also contains a "bar" as do about two-thirds of all spiral galaxies (see Figure 1). This overall structure of our Galaxy has been known for some time, but it is difficult to measure the spatial distribution and properties of distant stars because our Sun and Earth are located right in the Galaxy's thin disk of gas and dust. Distant stars are therefore often hidden behind gas and dust clouds, particularly in the direction of the galactic centre at a distance of 25 000 light-years (Figure 2).

The best view of the inner Galaxy is at near-infrared wavelengths, where the clouds become transparent. Such observations of a certain class of giant stars, the so-called red clump stars, have given us the best information about the Milky Way's inner regions so far. These stars have very uniform absolute luminosity and colour, therefore their distances and the residual dimming by dust can be determined from their apparent brightness and colour. With this information, their distribution along the line of sight can be reconstructed.

Milky Way
Figure 2: This 360-degree panoramic image, covering the entire southern and northern celestial sphere, shows the disk of the Milky Way, where the light of the bulge stars is hidden behind filaments of absorbing dust.
Credit: ESO/S. Brunier
Asymmetries in the distributions of these stars on both sides of the Galactic centre led astronomers to believe that the stars are arranged in a bar-like structure. The data even suggested two barred components, an inner elongated bulge, and an outer bar in the disk, with different orientations. Recent observations from the VVV survey at the ESO VISTA telescope have now shown that the asymmetries in the distributions of the red clump stars change again within about 2000 light-years from the Galactic centre. Does this imply a new nuclear bar component in the innermost Milky Way? And how could all these structures in the inner Milky Way have formed?

Using a computer simulation, scientists at the Max Planck Institute for Extraterrestrial Physics have now shown that the elongated bulge, the bar in the disk, and the distribution of stars around the centre of the Milky Way can all be explained with one and the same model, which also predicts how the bar is interacting with the spiral arms. The innermost region within 2000 light-years from the centre turns out to have higher density and rounder morphology than the cigar-shaped structure of the outer bulge (Figure 3).

Computer model
Figure 3: Computer model of a disk galaxy resembling the Milky Way. The image above shows a side view of the simulation, as one would see the galaxy from the position of the Earth. In the bottom left image the entire simulation is shown with a size of 50 000 light years on a side, the image at bottom right shows the central region with 16 000 light years on a side. In the left image, the distortion of the elongated bar is clearly visible, as it interacts with the spiral arms. The zoomed image on the right shows the structural changes near the centre where the stars have a rounder distribution.
Credit: MPE
"In our model, the galactic bulge is caused by dynamical instabilities in the disk," says Ortwin Gerhard, senior scientist of the research group at MPE. "Surprisingly, we could reproduce the newly discovered configuration with this model as well, without having to adjust the parameters to these observations in particular. All components, near the centre and farther out, form naturally in the evolution of a generic disk galaxy."

The simulation includes one million particles, which were initially arranged in an exponential disk and surrounded by a halo of dark matter. Over the course of 1-2 billion years instabilities develop that first lead to a bar-shaped structure and finally to a thickening in the centre, the elongated bulge. The fact that several of the structures in the Milky Way as seen from our position within the disk emerge naturally in such a simulation supports the hypothesis that our Milky Way started out as a pure disk galaxy and evolved without any large outside influence.

Original publication :
  The inner galactic bulge: evidence for a nuclear bar?,
Ortwin Gerhard and Inma Martinez-Valpuesta
external link ApJL, 744:L8 (5pp), 2012 January 1

Unifying a boxy bulge and planar long bar in the Milky Way
Inma Martinez-Valpuesta and Ortwin Gerhard
external link ApJL, 734:L20 (4pp), 2011 June 10

Contact :
  internal link Dr. Hannelore Hämmerle
Press Officer
Max-Planck-Institut für extraterrestrische Physik
phone: +49 89 30000-3980
email: hanneh@mpe.mpg.de
  internal link Dr. Ortwin Gerhard
Max-Planck-Institut für extraterrestrische Physik
phone: +49 89 30000-3539
email: gerhard@mpe.mpg.de
  ToPtop of page   Valid HTML 4.01! Last update: 2012-02-15 by link H. Steinle
Contact: link MPE public outreach department
© Max-Planck-Institut für extraterrestrische Physik