Lecture 3: The Stars and their Environment - PowerPoint PPT Presentation

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Lecture 3: The Stars and their Environment

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Title: Lecture 3: The Stars and their Environment


1
Lecture 3The Stars and their Environment
  • Dr Michael Burton

2
Fundamental Properties of Stars
  • Parallax gives distance to closest stars.
  • Light years.
  • Colours give temperature.
  • bluehot, yellowtepid (6000K), redcool.
  • Luminosity from 0.001 -100,000 x Sun.
  • Masses from binary star orbits (K3L).
  • 0.01 to 100 x Sun

3
Mass of the Sun
  • 2 x 1030 kilograms
  • 2 million, million, million, million, million kg
  • 2,000,000,000,000,000,000,000,000,000,000 kg
  • But not 2,000,000,000,000,000,000,000,000,000 kg
  • Or 2,000,000,000,000,000,000,000,000,000,000,000
    kg!

4
Hertzsprung-Russell Diagram
  • Fundamental tool for understanding stars.
  • Luminosity (or magnitude) vs
  • Temperature (or colour or spectral type).
  • Main Sequence
  • Red Giants
  • White Dwarfs
  • Position on MS determined by mass.

5
Nebulae Surrounding Star Birth
  • Collapse from Molecular Clouds under gravity (1
    106 1019 particles per cm-3).
  • Dark Nebulae (100 K).
  • Shine through fluorescing hydrogen gas.
  • Red Nebulae (HII regions) (10,000K).
  • Reflect starlight by dust scattering.
  • Blue Nebulae (cf the sky).

6
Star Birth
  • Protostar - collapsing core of molecular cloud.
    Pressure builds till nuclear fusion ignites in
    centre, becoming a star.
  • Associated with disks (planetary systems),
    outflows and jets.
  • Disperse their cocoon to become visible.
  • Typically form in clusters, dominated by light
    from 1-2 brightest members.

7
Stellar Evolution Main Sequence Life
  • Main Sequence stars gravity balances nuclear
    fusion of H to He at 15 million K.
  • More massive stars burn fuel more quickly.
  • Hydrogen shell burning when fuel exhausted in the
    core.
  • Star swells to a cool, extended Red Giant.
  • 3000K, Radius 1 AU.

8
Stellar Evolution Life on the HR Diagram
  • Leaves MS, climbs Giant Branch.
  • Turn-off point on HR diagram gives age.
  • Fusion of helium begins in core (at 100 million
    K), descends and contracts.
  • Helium shell ignites, sheds outer layers.
  • Globular clusters ancient star cities
  • Horizontal Branch stars burning helium.
  • HR diagram evolution as function of mass.

9
Star Death Low Mass Stars
  • Main Sequence to Red Giant to Planetary Nebula
    White Dwarf.
  • PN ejected envelope, forms expanding shell.
  • WD burnt out stellar core. Mass of star but size
    of Earth.
  • Teaspoon weighs 5 tons!

10
Star Death High Mass Stars
  • MS to Red Giant to Supergiant to Supernova to
    Neutron Star or Black Hole.
  • Nuclear fusion continues in shells to iron.
  • Protons electrons fuse to neutrons.
  • Unstable, collapses in lt1s. Bounce off rigid
    core detonates star - Supernova!
  • Shines as brightly as galaxy for a few days!

11
Stellar Remnants
  • Low mass stars White Dwarfs
  • High mass stars
  • supernova remnants, expanding at 10,000 km/s
  • may trigger future star formation?
  • Neutron stars mass star but just 10 km across.
  • Teaspoon weighs 100 million tons!
  • Seen as Pulsars, flashing beacons in space.
  • or Black Holes?

12
Black Holes
  • Gravity wins, even light cant escape!
  • Collapse to a Singularity with an Event
    Horizon (R 2GM/c2).
  • Mass, angular momentum and charge only.
  • Cosmic censorship, time slows down.
  • Supermassive Black Holes in galaxy cores.
  • Primordial Black Holes in Big Bang.
  • Black Holes evaporate through production of
    virtual particles at event horizon!
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