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The Milky Way I AST 112 Credit: Stephane Vetter
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How do we look at this…
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… and decide that it looks like this?
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The Milky Way Studying the Milky Way is “like trying to draw a picture of your house without ever leaving your bedroom.” It helps to compare it to other galaxies.
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The Milky Way Point a telescope at the cloudy band. It turns into countless stars.
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Studying the Milky Way Astronomers first tried to determine our location in the Milky Way by counting stars in different directions – Above and below the band of the Milky Way, they came up with roughly equal numbers of stars in all directions
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Structure of the Milky Way Herschel looked at 683 regions and counted stars Assumed: – Stars have same luminosity – Density of stars is constant – No extinction due to dust – Can see to edge of the distribution of stars The Sun is the large star near the center. Is that suspicious?
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Our Location in the Milky Way These observations suggested that we are at the center of the Milky Way – And why not? Away from the band, we see equal numbers of stars in all directions. Could it be that we only see our “neighborhood” and nothing beyond? – Why would that happen?
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Extinction If there is dust between the observer and the object, the object will look dimmer than it is – This is called extinction, and astronomers did not account for it early on
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Are we at the center? Seems to me… – If you look one way and see the band then look the other way and don’t see it, we’re not at the center!
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Are we at the center? Interstellar dust obscures most of the Milky Way The stars in our night sky are a small corner of our galaxy – Can only see so far into the disk – Dust thickest in disk (and we’re in the disk!) – Which direction has the least amount of dust? Only thanks to radio and IR can we look further in
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Our Location in the Milky Way Thus far we’ve used stars for these maps Globular clusters are a better indicator of our position in the Milky Way than individual stars – Brighter – Spherical distribution and out of the disc! – Harlow Shapely measured the spherical distribution of globular clusters (1920’s)
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Our Location in the Milky Way Shapley found: – Sun is 45,000 LY from center of Milky Way – (It’s actually 28,000 LY) Shapley’s value was off because he did not account for …? – What would make something look farther away (dimmer)? Globular clusters seen mostly toward Sagittarius – Where’s that?
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Sagittarius and the Galactic Center
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Spiral Arms Start by looking at other galaxies for this The arms are blue with red patches – What does this say about star formation?
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Spiral Arms Use H II regions and O/B type stars as tracers of spiral arms Don’t misinterpret the diagram – not center of Milky Way Sun is in Orion-Cygnus Arm
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Structure of the Milky Way Other than dust clouds, can you identify any structures in the band?
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Structure of the Milky Way A spiral galaxy with 100 billion+ stars Diameter is 100,000 LY The Sun is 28,000 LY from the center Components: – Bulge – Disk – Arms – Halo – SMBH (Supermassive black hole)
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Structure of the Milky Way The bulge is a spherical distribution stars in the center of a galaxy – Note the yellow / red color: they are older
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The Bulge We use infrared to look through dust and see the bulge We can look along lines with minimal extinction – E.g. Baade’s window; can past galactic center
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Structure of the Milky Way The disk is a 1000 LY thick pancake of younger, bluer stars Orbits are “orderly” – Same direction – Confined to disk The disk of the Milky Way contains the spiral arms
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Structure of the Milky Way Look closely to see that the spiral arms are structures within the disk.
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Structure of the Milky Way The halo contains a spherical distribution of: – Stars – Globular clusters – Dark matter
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Orbits in the Milky Way Orbits of disk stars are roughly circular – They rise and fall If it gets too far above the disk, it starts downward Overshoots – This gives the disk its 1000 LY thickness Orbits of halo and bulge stars are random
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Orbits in the Milky Way Orbits of disk and halo/bulge stars indicates that they have different origins, or perhaps formed at different stages.
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Mass of the Milky Way Kepler’s 3 rd Law relates orbital period to distance and mass – Excludes mass not contained within orbit Shapley measured the distance and we know orbital velocities
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