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Dr Martin Hendry University of Glasgow, UK (Basler Chair, 2005) HENDRY@etsu.edu Tel: 94252 Brown Hall, Room 373 Office Hrs: Mon 10.30 – 11.30 Tue 14.30 – 15.30. Astronomy II, Fall 2005 Lectures on galaxies and cosmology. http://www.astro.gla.ac.uk/users/martin/basler/astro2/.
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Dr Martin Hendry University of Glasgow, UK (Basler Chair, 2005) HENDRY@etsu.edu Tel: 94252 Brown Hall, Room 373 Office Hrs: Mon 10.30 – 11.30 Tue 14.30 – 15.30 Astronomy II, Fall 2005 Lectures on galaxies and cosmology http://www.astro.gla.ac.uk/users/martin/basler/astro2/
Late 18th Century: French astronomer Charles Messier compiles catalog of nebulae ( = Greek word for cloud )
The Whirlpool Nebula, M51, drawn from observations made with the Earl of Rosse’s Leviathan telescope, at Birr Castle in Ireland.
Early 20th Century The nature of the nebulae?… Gas clouds within the Milky Way, or “Island Universes” ?….
The Great Debate, 1920 Shapley vs Curtis at the National Academy of Sciences Shapley argues successfully that the nebulae are within the Milky Way
The Great Debate, 1920 Shapley vs Curtis at the National Academy of Sciences Shapley argues successfully that the nebulae are within the Milky Way Then Hubble measures distances to nebulae
1922: Hubble finds Cepheids in the Great Nebula in Andromeda
Surface temperature (K) 25000 10000 8000 6000 5000 4000 3000 . . . 106 . -10 . Deneb . . . . Rigel . . . . Betelgeuse CEPHEIDS . . . . . Antares 104 . -5 . . . . . . . . . . . . . Arcturus . . . Aldebaran . . . . . . . . . . . . Regulus . . . . . . . 102 Vega . . . . . 0 . . . Mira Sirius A . . . . . . Pollux . Procyon A . . . . Luminosity (Sun=1) . . Altair Sun Absolute Magnitude 1 . . . +5 . . . . . . . . . . . . . . . 10-2 . +10 . . . . . . . . . . . . . . . . Barnard’s Star . . . . Sirius B . . . . 10-4 . +15 . . Procyon B . . . . O5 B0 A0 F0 G0 K0 M0 M8 Spectral Type Cepheids are bright, young F- and G-type supergiants. Their period-luminosity relation makes them good standard candles. Measuring their period lets us estimate their distance.
Luminosity and flux Apparent brightness, or flux, falls off with the square of the distance, because the surface area of a sphere increases with the square of its radius Distance, (metres) Luminosity, (watts) Flux, (watts / square metre)
Measuring Astronomical Distances: Parallax Even the nearest star shows a parallax shift of only 1/2000th the width of the full Moon
Measuring Astronomical Distances: Parallax parallax angle A star at a distance of 1 parsec shows a parallax angle of one arc second
Measuring Astronomical Distances: Parallax parallax angle
Cepheid Variables: Cosmic Yardsticks Henrietta Leavitt 1908-1912
Cepheid Variables: Cosmic Yardsticks • Leavitt studied Cepheids in the Large Magellanic • Cloud, a satellite galaxy of the Milky Way and • known even then to be very distant. • Differences in apparent brightness of LMC • Cepheids must be due to differences in intrinsic • brightness. Henrietta Leavitt 1908-1912
Hubble measured distances to dozens of nebulae. Even the nearest, in Andromeda, was millions of light years distant
Hubble measured distances to dozens of nebulae. Even the nearest, in Andromeda, was millions of light years distant When we look at the Andromeda Galaxy in the night sky, the light we are seeing set off more than 2 million years ago, before there were any humans on Earth.
Hubble then embarked on a systematic classification of nearby galaxies. He identified three main types: • Spirals • Ellipticals • Irregulars • The spirals also subdivide into barred and unbarred • Hubble’s classification is often represented by a tuning fork diagram
a = semi-major axis b = semi-minor axis Elliptical classification E0 E3 E7
Spiral classification Sa Sb Sc Barred spiral classification SBa SBb SBc
Surface temperature (K) 25000 10000 8000 6000 5000 4000 3000 . . . 106 . -10 . Deneb . . . . Rigel . . . . Betelgeuse . . . . . Antares 104 . -5 . . . . . . . . . . . . . Arcturus . . . Aldebaran . . . . . . . . . . . . Regulus . . . . . . . 102 Vega . . . . . 0 . . . Mira Sirius A . . . . . . Pollux . Procyon A . . . . Luminosity (Sun=1) . . Altair Sun Absolute Magnitude 1 . . . +5 . . . . . . . . . . . . . . . 10-2 . +10 . . . . . . . . . . . . . . . . Barnard’s Star . . . . Sirius B . . . . 10-4 . +15 . . Procyon B . . . . O5 B0 A0 F0 G0 K0 M0 M8 Spectral Type
Evolution and the Tuning Fork diagram For many years the prevailing belief was that ellipticals evolve into spirals, from left to right in the tuning fork (although Hubble did not argue for the tuning fork diagram as an evolutionary sequence). But spirals contain many newly-formed stars. Do spirals evolve into ellipticals?... However, spirals contain many old stars too. Now generally accepted that spirals and ellipticals evolved separately, as part of a much more complex overall pattern of galaxy formation. (See later)
Our Local Neighborhood The Milky Way is part of a small cluster of about 30 galaxies called the Local Group. The Local Group is roughly disc-shaped and about 2 Mpc in diameter. The dominant members of the Local Group are the MilkyWay and the Andromeda galaxy These two spirals dominate LG dynamics, and contain most of the luminous matter. Remaining members are dwarf ellipticalsand irregulars.