Interstellar Medium by Eye

Transcription

1 Interstellar Medium by Eye Nebula Latin for cloud = cloud of interstellar gas & dust Wide angle: Milky Way Summer Triangle (right) α&β Centauri, Coal Sack Southern Cross (below)

2 Dust-Found in the Plane of a Galaxy Whirlpool and NGC 891 galaxies

3 Trifid Nebula Emission, Reflection, Dark Nebulae Red, Blue, Black

4 Emission Nebula IC1396 Emission Nebula = HII region composed of ionized hydrogen

5 H II Region Star hotter than B1V emits Ultraviolet ionizing Hydrogen gas Bubble nebula

6 Emission Nebula Spectrum Fluorescence caused by Ultraviolet light from hot stars Color of nebulae depend on filters

7 Barnard Object = Dark Nebula Dark Nebula=Molecular Clouds=Molecular Hydrogen =H 2 Temperature ~30K Density 10 4 atoms/cubic cm Dust grains so dense the Dark Nebula blocks all the starlight

8 Reflection Nebula: Pleiades Reflection Nebula caused when star(s) are not hot enough to ionize hydrogen = neutral hydrogen = H I region ~100K Dust grains scatter the starlight

9 Why the Sky is Blue?

10 Figure 10.1a Interstellar Extinction Dust makes the stars redder and fainter

11 Interstellar Reddening Blue photons scatter more easily than red photons So a star s color is redder seems cooler Spectral type is unchanged So difference in color (B-V) measures extinction (dimming)

12 Interstellar Dust Grains Carbon chains coated with ices about mm = 0.5 micron Grain formed in Red Giant atmosphere found in meteorite (different isotopic abundances)

13 Light is Wave Sunlight vibrating side to side is reflected Glare is eliminated by sunglasses with lines going up and down

14 Dust Causes Polarization Dust grains aligned by galactic magnetic field Direction of field and amount of dust measured by looking at a distant star thru polarizer

15 Interstellar Absorption Lines Cool low pressure foreground gas produces thin absorption lines of wrong ionization /temperature /radial velocity Or stationary absorption lines in spectroscopic binaries

16 Interstellar Medium = ISM In ISM approximately 1 atom per cubic centimeter and on Earth 30,000,000,000,000,000,000 per cubic centimeter 75% Hydrogen, 24%Helium, 1% rest

17 Interstellar Medium The nebulosity near stars is easy to see What about away from the stars?

18 Coronal Gas Ejected by Supernovae Seen in X-ray and Ultraviolet Millions Kelvin Gas is cycled back into stars

19 Giant Molecular Clouds Molecules of Hydrogen, Carbon Monoxide, etc. Very cold ~ 20 Kelvin 10,000 atoms /cm pc diameter 100-1,000,000 solar masses

20 Electronic, Vibrational, Rotational Transitions Hydrogen only emits in UV/Visible so use CO to map Galaxy Millimeter wavelengths not absorbed by dust

21 Trifid Nebula Lots of formaldehyde found in dusty lanes Where it is protected from UV and Visible light Temperature sinks to 10K

22 146 Different Molecules Found Dust in GMC shields interior where molecules form Including complex carbon molecules up to H(CC) 5 CN

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24 Intercloud medium Intercloud medium is H II = ionized hydrogen Temperature of thousands of degrees Density of 0.1 atom/cm 3

25 Four Components of ISM Cold Molecular clouds Cool neutral HI clouds Warm intercloud medium HII Hot Coronal Gas

26 Heliosphere Sun ploughs through Interstellar Medium

27 Local Interstellar Clouds Approximately 10 parsecs

28 Local Bubble 120 pc map

29 Local Bubble & Galactic Neighbors Surrounding 500pc Four Components of ISM Giant Molecular Cloud = star forming region -orange Local interstellar HI cloud - violet Local Bubble HII - black Vela SN Remnant = Coronal - pink

30 Interstellar Extinction Curve Dust is not just in clouds UV scattered more than IR so very small particles (1μ) Some kind of carbon molecule makes the bump

31 Equal Pressure Among 4 Components Speed/kinetic energy of particles depends on temperature 30K=>300meters/sec = 1000km/hour Pressure = Density X Temperature X constant Pressure = number of particles X how fast they are moving