* Astronomy

Title: Star Formation in the Most Distant Molecular Cloud in the Extreme Outer Galaxy: A Laboratory of Star Formation in an Early Epoch of the Galaxy's Formation
Authors: Naoto Kobayashi (IoA, Univ. of Tokyo), Chikako Yasui (IoA, Univ. of Tokyo), Alan T. Tokunaga (IfA, Univ. of Hawaii), Masao Saito (ALMA, NAOJ)

We report the discovery of active star formation in Digel's Cloud 2, which is one of the most distant giant molecular clouds known in the extreme outer Galaxy (EOG). At the probable Galactic radius of ~20 kpc, Cloud 2 has a quite different environment from that in the solar neighbourhood, including lower metallicity, much lower gas density, and small or no perturbation from spiral arms. With new wide-field near-infrared (NIR) imaging that covers the entire Cloud 2, we discovered two young embedded star clusters located in the two dense cores of the cloud. Using our NIR and 12CO data as well as HI, radio continuum, and IRAS data in the archives, we discuss the detailed star formation processes in this unique environment. We show clear evidences of a sequential star formation triggered by the nearby huge supernova remnant, GSH 138-01-94. The two embedded clusters show a distinct morphology difference: the one in the northern molecular cloud core is a loose association with isolated-mode star formation, while the other in the southern molecular cloud core is a dense cluster with cluster-mode star formation. We propose that high compression by the combination of the SNR shell and an adjacent shell caused the dense cluster formation in the southern core. Along with the low metallicity range of the EOG, we suggest that EOG could be an excellent laboratory for the study of star formation processes, such as those triggered by supernovae, that occurred during an early epoch of the Galaxy's formation. In particular, the study of the EOG may shed light on the origin and role of the thick disk, whose metallicity range matches with that of the EOG well.

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Integral mapped the glow of 511 keV gamma rays from electron-positron annihilation. The map shows the whole sky, with the galactic center in the middle. The emission extends to the right.
Credit: ESA/Integral/MPE/G. Weidenspointner

Title: OGLE-II High Proper Motion Stars towards the Galactic centre
Authors: Nicholas J. Rattenbury, Shude Mao

The photometry data base of the second phase of the OGLE microlensing experiment, OGLE-II, is a rich source of information about the kinematics and structure of the Galaxy. In this work we use the OGLE-II proper motion catalogue to identify candidate stars which have high proper motions. 521 stars with proper motion mu > 50 mas/yr in the OGLE-II proper motion catalogue (Sumi 2004) were cross-identified with stars in the MACHO high proper motion catalogue, and the DENIS and 2MASS infra-red photometry catalogues. Photometric distances were computed for stars with colours consistent with G/K and M type stars. 6 stars were newly identified as possible nearby (< 50 pc) M dwarfs.

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A ragged company of stars is rushing through the chaotic core of our galaxy, travelling faster than can easily be explained. The new measurement of its path, made with the 10-metre Keck telescope in Hawaii, US, also deepens a mystery surrounding the Milky Way's central black hole.
The Arches cluster is a group of young stars only about 100 light years from the very centre of the galaxy, a dangerous region where strong gravitational fields can tear a star cluster apart.

"The Arches will only survive a few million years" - Andrea Stolte of the University of California in Los Angeles, US.

Stolte is a member of the team that has now tracked the cluster's trajectory. They took one image of the cluster in 2002 using the 8-metre Very Large Telescope (VLT) in northern Chile, and then another in 2006 using Keck.
They got a precise fix on the cluster using Keck's "laser guide star" system, in which a laser hits sodium atoms in the upper atmosphere to create an artificial star. By monitoring the guide star, the optics of the telescope can adapt in real time to disturbances in the atmosphere, which would otherwise blur the image.
The team found that after four years the cluster, which lies 25,000 light years away, had moved by seven millionths of a degree. That corresponds to a speed through space of more than 200 kilometres a second.
That is puzzlingly fast. The cluster is thought to have formed when two gas clouds in the inner galaxy collided but the most likely candidate clouds are travelling much more slowly than the Arches cluster.

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Position (J2000): RA 17h 46m 22s | Dec -28º 51' 36.4"