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Post Info TOPIC: Andromeda galaxy (M31)


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RE: Andromeda galaxy (M31)
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This colour-coded Chandra image (red/low energy, green/medium energy, and blue/high energy X-rays) shows the central region of the Andromeda Galaxy, a.k.a. M31 where a diffuse, X-ray emitting cloud of hot gas was discovered in the midst of a collection of point-like sources.

m31_001

The image is 28 arcmin per side
Credit: NASA

Analysis of the X-ray data shows that the point sources are associated with binary star systems that contain a neutron star or black hole that is pulling matter away from a normal star. As the matter falls toward the neutron star or black hole, it is heated by frictional forces to tens of millions of degrees, and produces X-rays.
The diffuse X-ray cloud is due to gas that has accumulated in the central region and been heated to millions of degrees, probably by shock waves from supernova explosions. The energy input from the supernovas could also be driving gas out of the central region. This process may affect both the shape and evolution of the galaxy by depleting the raw material for the formation of new stars and preventing more gas from accumulating there.

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Dr. Pauline Barmby of the Harvard-Smithsonian Center for Astrophysics, Cambridge and her colleagues recently observed the Andromeda galaxy using the Spitzer space telescope.

Barmby and her team used the Spitzer data to make drastically improved measurements of Andromeda's infrared brightness. They found that the galaxy shines with the same amount of energy as about 4 billion suns. Based on these measurements, the astronomers confirmed that there are roughly 1 trillion stars in the galaxy. Our Milky Way galaxy is estimated to house a couple of hundred billion stars.

"This is the first time the stellar population of Andromeda has been determined using the galaxy's infrared brightness. It's reassuring to know our numbers are in agreement with previous estimates of the mass of the stars based on the stars' motion" - Dr. Pauline Barmby.

andromedafaulse
Credit NASA

The new false-coloured portrait also provides astronomers with the best look yet at the dust-drenched spiral arms that swirl out of the galaxy's centre, a region hidden by bright starlight in visible-light images. Dust and gas are the building materials of stars. They are clumped together throughout the spiral arms, where new stars are forming.

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Title: Discovery of an Extended Halo of Metal-poor Stars in the Andromeda Spiral Galaxy
Authors: Puragra Guhathakurta, James C. Ostheimer, Karoline M. Gilbert, R. Michael Rich, Steven R. Majewski, Jasonjot S. Kalirai, David B. Reitzel, Michael C. Cooper, Richard J. Patterson

Researchers report on the discovery of an extended halo of metal-poor red giant branch (RGB) stars in the Andromeda spiral galaxy (M31).
Their ongoing survey of M31 includes wide-field deep optical images in the intermediate-width DDO51 band and Washington system M and T_2 bands obtained with the Kitt Peak National Observatory 4-m telescope and Mosaic camera. The DDO51 band allows them to screen M31 RGB star candidates from foreground Galactic dwarf star contaminants.
The imaging is followed up with spectroscopy using the Keck II 10-m telescope and DEIMOS. A combination of photometric and spectroscopic diagnostics is used to reliably isolate M31 RGB stars; these stars are seen in all of the fields out to a projected distance of 165 kpc from M31's centre.

These newly discovered RGB stars represent the hitherto elusive stellar halo of M31. The surface brightness of M31 beyond r > 30 kpc is characterised by a power law, r^{-2.6 ± 0.3}, distinct from the Sersic profile that characterises its extended bulge.
Their data show that M31 is 3-5 times larger than any of its previously mapped spheroidal/disk components. Together, the Galactic and M31 halos span > 1/3 of the distance between them, suggesting that stars occupy a substantial volume fraction of our Local Group, and possibly most galaxy groups.


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Title: The Central Regions of M31 in the 3 - 5 micron Wavelength Region
Authors: T. J. Davidge, Joseph B. Jensen, K. A. G. Olsen

Images obtained with NIRI on the Gemini North telescope are used to investigate the photometric properties of the central regions of M31 in the 3 - 5 micron wavelength range. The light distribution in the central arcsecond differs from what is seen in the near-infrared in the sense that the difference in peak brightness between P1 and P2 is larger in M' than in K'; no obvious signature of P3 is detected in M'. These results can be explained if there is a source of emission that contributes ~ 20% of the peak M' light of P1 and has an effective temperature of no more than a few hundred K that is located between P1 and P2. Based on the red K-M' colour of this source, it is suggested that the emission originates in a circumstellar dust shell surrounding a single bright AGB star. A similar bright source that is ~ 8 arcsec from the centre of the galaxy is also detected in M'. Finally, the (L', K-L') colour-magnitude diagram of unblended stars shows a dominant AGB population with photometric characteristics that are similar to those of the most luminous M giants in the Galactic bulge.



The K' (top) and M' (middle) images of the centre of M31. A 2×4-arcsec region is displayed for each filter, and the data have been rotated so that the line connecting P1 and P2 falls along the horizontal axis. The images are displayed with the same stretch after being normalised to the same peak P1 brightness. Note that while P1 and P2 form an elongated structure in K', P1 is more dominant with respect to P2 in M'. The bottom image is the model described in §3, in which a point source, offset by 0.1 arcsec from the centre of P1 along the P1 – P2 axis and contributing 20% of the peak light from P1, has been added to the K' image. This simple model reproduces the overall appearance of the centre of M31 near 4.6µm.

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A new study suggests that the Milky Way and its nearest galactic neighbour, Andromeda had similar beginnings and evolved in similar ways, at least over their first several billion years.

Astronomers had previously thought that Andromeda’s stellar halo was metal-rich while the Milky Way’s halo was metal-poor but a new study lead by Scott Chapman of the California Institute of Technology has found that are similarly impoverished when it comes to metals suggests they share similar evolutionary histories

The bulk of the complex structure in Andromeda's outer region is rotating with the disk is a blessing for studying the true underlying stellar halo of the galaxy. All the inhomogeneous fuzz seen in the image above can be lifted off and removed from consideration, yielding a sample of about 1000 stars which appear as a metal-poor ([Fe/H] = -1.4) 'pure' stellar halo sample. Using this new information, careful measurements of the random motions of the stars in the stellar halo have been made, probing it's mass and the form of the elusive dark matter which surrounds it.
The new measurements of the stellar velocities in M31's halo show that M31's halo is remarkably similar to our own Milky Way.


300 kpc x 300 kpc box, showing different simulations of a stellar halo in a Milky Way or M31 type galaxy.

The results are made possible by technological advances in astrophysics. In this case, the Keck/DEIMOS multi-object spectrograph affixed to the Keck-II telescope possesses the mirror size and light-gathering capacity to image stars that are very faint, and the spectrographic sensitivity to obtain highly accurate radial velocities.

The study could lead to new insights on the nature of dark matter. This is the first time astronomers have been able to obtain a panoramic view of the motions of stars in the halo of a galaxy. These stars allow them to weigh the dark matter, and determine how it decreases with distance. While no one yet knows what dark matter is made of, its existence is well established because of the mass that must exist in galaxies for their stars to orbit the galactic centres the way they do.
Current theories of galactic evolution, in fact, assume that dark-matter wells acted as a sort of "seed" for today's galaxies, with the dark matter pulling in smaller groups of stars as they passed nearby.

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Andromeda X
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Astronomers have discovery of a new galaxy orbiting Andromeda .

Andromeda X--the "X" is the Roman numeral ten--is a magnitude -8.1 dwarf spheroidal galaxy, a diffuse collection of stars spread out from one another.
The galaxy was discovered from the Sloan Digital Sky Survey data, and confirmed with the 4.2-meter William Herschel Telescope and the 2.5-meter Nordic Optical Telescopes in the Canary Islands.



Daniel Zucker of the Max Planck Institute for Astronomy in Heidelberg, Germany, and his colleagues find that the brightest stars in Andromeda X are red giants. but, the stars in Andromeda X have only about 1 percent of the solar abundance of iron and other heavy elements.

Projected distribution of M31’s nearest satellites, with the addition of And IX and And X. The inner ellipse indicates the rough optical size of M31’s disk, and the outer ellipse the approximate extent of the INT survey. The coverage of the SDSS M31 scan is shown by the long stripe along the major axis of M31.

The red giants' brightness indicates that Andromeda X is slightly closer to us than the Andromeda Galaxy is. Whereas Andromeda's distance from Earth is 2.5 million light-years, Zucker's team estimates Andromeda X is 2.2 to 2.4 million light-years from us. The small galaxy is 280,000 to 450,000 light-years from Andromeda's centre. Its angular separation from the centre of the Andromeda Galaxy is 5.5 degrees, about the same as the separation between the two "pointer stars" in the Big Dipper's bowl.


Andromeda X is the fifteenth known satellite of the Andromeda Galaxy.


Andromeda X, A New Dwarf Spheroidal Satellite of M31: Photometry
Authors: Daniel B. Zucker, Alexei Y. Kniazev, David Martinez-Delgado, Eric F. Bell, Hans-Walter Rix, Eva K. Grebel, Jon A. Holtzman, Rene A. M. Walterbos, Constance M. Rockosi, Donald G. York, J. C. Barentine, Howard Brewington, J. Brinkmann, Michael Harvanek, S. J. Kleinman, Jurek Krzesinski, Dan Long, Eric H. Neilsen, Jr., Atsuko Nitta, Stephanie A. Snedden

We report the discovery of Andromeda X, a new dwarf spheroidal satellite of M31, based on stellar photometry from the Sloan Digital Sky Survey (SDSS). Using follow-up imaging data we have estimated its distance and other physical properties. We find that Andromeda X has a de-reddened central surface brightness of mu_V,0 ~ 26.7 mag arcsec^-2 and a total apparent magnitude of V_tot ~ 16.1, which at the derived distance modulus, (m - M)_0 ~ 24.12 - 24.34, yields an absolute magnitude of M_V ~ -8.1 +/- 0.5; these values are quite comparable to those of Andromeda IX, a previously-discovered low luminosity M31 satellite. The discoveries of Andromeda IX and Andromeda X suggest that such extremely faint satellites may be plentiful in the Local Group.

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Andromeda IX
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Astronomers from the Sloan Digital Sky Survey (SDSS) have discovered the faintest galaxy yet. Even better news is that it’s right in our cosmic background. The new galaxy is named Andromeda IX and is a dim bulb in the cosmological scheme of things. It is nearly twice as faint as the previous lowest luminosity record holder is: Ursa Minor dwarf spheroidal galaxy. Andromeda IX is situated near M31, the Andromeda galaxy, and is so diffuse that it appears 100 times dimmer than the night sky, and 100,000 times fainter than the Milky Way...

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A new study has revealed that most of the Andromeda galaxies small satellite galaxies, are lined up in a single plane that slices through Andromeda's spiral disc. The alignment suggests the satellites are either floating on a river of dark matter or are the remains of a larger galaxy Andromeda has already cannibalised.
Astronomers have known for about 25 years that the Milky Way's dozen or so satellites line up along two planes that lie perpendicular to its disc. But how the structures formed is still not clear. So a team led by Eva Grebel of the University of Basel in Binningen, Switzerland, set out to discover whether similar planes exist around Andromeda. At a distance of 2.7 million light years, Andromeda is the nearest large, spiral galaxy similar to the Milky Way.
The researchers plotted the positions of Andromeda's 14 satellites using images from the Hubble Space Telescope and found that nine of them lay in a relatively thin plane about 52,000 light years wide.


Two-thirds of the small satellite galaxies around Andromeda line up in a plane perpendicular to Andromeda's disc
(Image: U Basel/NOAO/AURA/NSF/Keck Obs)


"It's unlikely such a plane would arise by chance" Eva Grebel .

The satellites in the plane also shared similar characteristics – most were faint, low in mass, and had already stopped forming stars.
The team believes the plane could have formed in several ways. In one scenario, the galaxies may have fallen towards Andromeda along an invisible filament of dark matter. Computer simulations show these filaments can form a cosmic "web" along which galaxies flow.
Distant observations show evidence for the filaments, since maps of the universe's large-scale structure reveal thousands of galaxies lining up along intersecting streams. But such filaments have not yet been detected near the Milky Way.

"One question is, could we see such filaments in our immediate surroundings?" - Eva Grebel .

Two fairly significant masses do lie on either side of Andromeda, with the spiral galaxy M33 just 720,000 light years away and a group of about three dozen galaxies called M81 about 11 million light years away. If a dark matter filament connects all three, future observations may show Andromeda's satellites moving along the filament.
Alternatively, the satellites may represent the remains of a more massive galaxy that was torn up and partly digested. When that galaxy began to interact with Andromeda, it would have broken up into smaller pieces, with some falling into the larger galaxy and others surviving.

"If this is correct, we expect these should have maintained the orbit of the original galaxy from which they came and we should see something that moves along this plane" - Eva Grebel .

But current telescopes cannot measure such subtle motions at Andromeda's distance, so the final verdict may come with future star-mapping satellites, to be launched within a decade.

"I enjoyed this result very much because it's getting at this very simple question - how did our own backyard get assembled?" - Michael Turner, astrophysicist at the University of Chicago in Illinois, US, who was not part of Grebel's team.

The research was presented on Wednesday at a meeting of the American Astronomical Society in Washington DC, US.

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M31VJ00443799+4129236
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For the first time, an eclipsing binary has revealed the precise distance to the Andromeda Galaxy (M31), say astronomers in Spain, America, and Scotland. The distance is in excellent agreement with other, less direct determinations.

Andromeda is the largest and most luminous galaxy in the Local Group. Knowing its distance helps scientists determine the distances of more remote galaxies. In the past, astronomers have determined M31's distance by observing its stars, notably its Cepheids and RR Lyraes, but deducing these stars' intrinsic brightness has depended on observations in other galaxies.

Now, Ignasi Ribas of the Spanish Research Council (CSIC) and the Institute for Space Studies of Catalonia (IEEC) and his colleagues have determined Andromeda's distance directly, by observing a 19th-magnitude eclipsing binary in one of the galaxy's spiral arms. The binary, known as M31VJ00443799+4129236, has two hot blue stars of spectral types O and B. As the stars orbit each other every 3.54969 days; they pass in front of and behind each other.

Astronomers have long used eclipsing binaries in the Milky Way to measure distances. The longer an eclipse lasts, the bigger the eclipsing star must be. The bigger and hotter the star, the more light it emits. Knowing each star's size and temperature therefore yields the pair's luminosity. Comparing the luminosity with the apparent brightness then reveals the system's distance.


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For 21 nights spread over 4 years, Ribas and his colleagues used the 2.5-meter Isaac Newton Telescope in the Canary Islands to observe the Andromeda binary's varying brightness at blue and yellow wavelengths. The astronomers also used the 8-meter Gemini North telescope in Hawaii to measure the stars' velocities, which vary as they orbit each other.

From these observations, the team determined the stars' properties. The O star has a temperature of 33,900 kelvins, a mass 23 times the Sun's, and a diameter 13.1 times the Sun's. The B star's temperature is 27,700 kelvins, its mass is 15 solar masses, and its diameter is 11.3 solar diameters. The stars' centres are 16.5 solar diameters apart, and the B star is spilling material onto the O star. Most importantly, the stars' absolute magnitudes are –5.29 and –4.66.

By comparing the absolute and apparent magnitudes, Ribas's team concluded the Andromeda Galaxy is 2.52±0.14 million light-years from Earth. This agrees perfectly with the Cepheid-based distance to Andromeda: 2.5 million light-years. The newly determined distance, however, does not depend on assuming a distance to the Large Magellanic Cloud. The agreement means astronomers can probably trust Cepheid distances to more distant galaxies, such as those in the Virgo and Fornax clusters.

Ribas and his colleagues plan to use other eclipsing binaries in Andromeda to further refine the galaxy's distance. They will publish their work in a future issue of Astrophysical Journal Letters.

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RE: Andromeda galaxy (M31)
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NASA's Spitzer Space Telescope has captured a stunning infrared view of Messier 31, the famous spiral galaxy also known as Andromeda.
Andromeda is the most-studied galaxy outside our own Milky Way, yet Spitzer's sensitive infrared eyes have detected captivating new features, including bright, aging stars and a spiral arc in the centre of the galaxy. The infrared image also reveals an off-centred ring of star formation and a hole in the galaxy's spiral disk of arms. These asymmetrical features may have been caused by interactions with the several satellite galaxies that surround Andromeda.


Expand (4.1Mb, 3000x1650)
Position (2000): RA: 00h42m44.3s Dec: +41d16m09s
Distance: 780,000 pc; 2.5 million light-years
Constellation: Andromeda

"Occasionally small satellite galaxies run straight through bigger galaxies. It appears a little galaxy punched a hole through Andromeda's disk, much like a pebble breaks the surface of a pond" - Dr. Karl Gordon, Steward Observatory, University of Arizona, Tucson, lead investigator of the new observation.

Approximately 2.5 million light-years away, Andromeda is the closest spiral galaxy and is the only one visible to the naked eye. Unlike our Milky Way galaxy, which we view from the inside, Andromeda is studied from the outside. Astronomers believe that Andromeda and the Milky Way will eventually merge together.
Spitzer detects dust heated by stars in the galaxy. Its multiband imaging photometer's 24-micron detector recorded approximately 11,000 separate infrared snapshots over 18 hours to create the new comprehensive mosaic. This instrument's resolution and sensitivity is a vast improvement over previous infrared technologies, enabling scientists to trace the spiral structures within Andromeda to an unprecedented level of detail.

"In contrast to the smooth appearance of Andromeda at optical wavelengths, the Spitzer image reveals a well-defined nuclear bulge and a system of spiral arms" - Dr. Susan Stolovy, a co-investigator from the Spitzer Science Centre at the California Institute of Technology, Pasadena.

The galaxy's central bulge glows in the light emitted by warm dust from old, giant stars. Just outside the bulge, a system of inner spiral arms can be seen, and outside this, a well-known prominent ring of star formation.

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