Life cycle of a star - PowerPoint PPT Presentation

1 / 34
About This Presentation
Title:

Life cycle of a star

Description:

Life cycle of a star Birth of Stars All stars are born in nebulae, huge clouds of dust and gas These collapse under gravitational forces, forming protostars These ... – PowerPoint PPT presentation

Number of Views:381
Avg rating:3.0/5.0
Slides: 35
Provided by: myteacher
Category:
Tags: cycle | life | of | star | stars

less

Transcript and Presenter's Notes

Title: Life cycle of a star


1
Life cycle of a star
2
Birth of Stars
  • All stars are born in nebulae, huge clouds of
    dust and gas
  • These collapse under gravitational forces,
    forming protostars
  • These young stars undergo further collapse,
    forming main sequence stars once fusion starts
  • Protostars that are too small (lt0.08 Msun) never
    ignite and become brown dwarves

3
Dumbbell Nebula
4
Large Ant Nebula
5
Horsehead Nebula
6
Protostars to StarsGravitational Collapse
  • Gravity pulls matter into the center of the
    protostar
  • The force of gravity accelerates the incoming
    particles
  • As particles collide they give up their kinetic
    energy as heat
  • If the star is massive enough, 30 million years
    later core temperatures reach 1.0 X 107 K, hot
    enough for fusion

7
Protostars to StarsFusion Begins
  • Electrons are stripped off to form a plasma at
    high temperatures
  • Density increases, nuclei are 10-15 m apart
    (touching)
  • Strong nuclear force overcomes electrostatic
    repulsion between nuclei
  • Fusion begins

8
A Star is Born
500 light years away
  • Fusion of small nuclei releases energy
  • Fused nuclei weigh a little less than the nuclei
    they were formed from
  • Mass defect becomes energy
  • Emc2
  • Thermal pressure due to increasing temperature
    balances gravitational contraction
  • A stable star forms

New stars
Protostars
http//www.nasa.gov/images/content/107455main_regi
on_88_lgweb.jpg
9
How Do We Know What a Star is Made of?
  • Disperse the light from the star
  • Look at atomic emission or absorption spectra

10
The Big Idea
  • A stars life cycle will depend on its mass
  • The bigger its mass, the shorter its life
  • The bigger its mass, the hotter it is
  • Stars less than 0.08 Msun never ignite!
  • Stars greater than 100 Msun cant resist thermal
    pressure so they explode
  • The hotter it is, the faster it will convert H to
    He

11
Classifying Main Sequence Stars
  • Three sizes
  • Sun-like stars
  • up to 1.5 X the mass of the sun
  • Huge stars
  • 1.5-3 X the mass of the sun
  • Giant stars
  • More than 3X the mass of the sun

12
(No Transcript)
13
Relative Star Sizes
http//www.essex1.com/people/speer/main.html
14
Classifying Stars
  • Stars differ in
  • Mass
  • Color
  • Related to their surface temperature
  • Blue is hotter than yellow which is hotter than
    red
  • Brightness
  • Related to how much energy the star is producing
    and how far away the star is

http//images.usatoday.com/tech/_photos/2005/03/10
/stars-main.jpg
15
Star Color Depends on Surface Temperature
  • Peak of curve gives you the color
  • The hotter the surface, the more energy at all
    wavelengths

visible light
www.warren-wilson.edu/.../WebCamPub/Webcam.htm
16
New Vocabulary
  • Apparent brightness
  • How bright the star looks to our eyes
  • Luminosity
  • Total amount of light energy a star emits
  • Usually given relative to the sun as Lsun1
  • Most luminous are 106 Lsun

17
Young Starsare Main Sequence Stars
  • These stars' energy comes from nuclear fusion,
    converting H to He
  • 90 of all stars are main sequence stars
  • For these stars, the hotter they are, the
    brighter they are
  • The hotter they are, the quicker they burn out
  • The sun is a typical main sequence star
  • Formed 5 billion years ago
  • Likely to last another 5 billion years

18
(No Transcript)
19
Forming Red Giants and Supergiants
  • Eventually the H in the core is all converted to
    He
  • Thermal pressure decreases, star collapses inward
  • Star reheats as it collapses, igniting He fusion
    to C in the core at higher temperature
  • Outer shell blows up in size, but cools off
  • 100X bigger diameter
  • Temperature is about 4000 K
  • Star moves off Main Sequence in H-R Diagram

20
(No Transcript)
21
Dying Sun-Like Stars
  • Fuel for fusion runs out
  • Outer shell blows out forming planetary nebula
  • Star collapses and reheats
  • Collapse is halted by degeneracy pressure
  • Electrons cant be shoved too close together
  • White dwarf is formed

22
White Dwarves
  • Very hot because of gravitational collapse
  • No energy production so can only cool by
    radiating energy
  • Eventually becomes a black dwarf
  • 80 of mass of original star, but now the size of
    earth

23
(No Transcript)
24
Life Cycle of Massive Stars
25
The Fate of Red Supergiants
  • Massive stars burn a succession of elements as
    fuel
  • When He runs out, big enough to collapse and get
    hot enough to fuse C to heavier nuclei, cycling
    up to Fe

http//imagine.gsfc.nasa.gov/docs/teachers/lifecyc
les/life_cycles_v2.1.ppt282,21,The End of the
Line for Massive Stars
26
The Fate of Red Supergiants
  • Fusion beyond Fe requires addition of extra
    energy, so star cools
  • Collapse is incredibly fast, then Supernova
    explosion over in a few minutes
  • All heavier elements are formed

Crab Nebulaleftover of supernova in 1054 AD
http//www.etacarinae.net/Spaceart/crabhighres.jpg
27
Before and After
28
Elements from Supernovae
  • Elements are spewed out into space during the
    explosion
  • We can identify these elements from the
    wavelengths of their X-ray emissions

All X-ray Energies
Silicon
http//imagine.gsfc.nasa.gov/docs/teachers/lifecyc
les/life_cycles_v2.1.ppt291,25,Elements from
Supernovae
Calcium
Iron
29
Whats Left Neutron Stars
  • Neutron stars are really dense and small
  • Electrons and protons fuse to form neutrons
  • 1.4 - 3 Msun compressed into a ball with radius
    of 10 km (smaller than Warren!)
  • A thimbleful would weigh more than 100 million
    tons on earth
  • Neutron stars are really hot
  • Surface is 1,200,000 F

http//observe.arc.nasa.gov/nasa/space/stellardeat
h/stellardeath_3ci.html
30
Neutron Stars are Pulsars
  • Neutron stars can sometimes be detected as
    pulsars
  • Conservation of angular momentum makes them spin
    up to 100 X second
  • Huge magnetic fields focus X-ray or light
    emission into cones
  • Lighthouse effect

http//imagine.gsfc.nasa.gov/Images/basic/xray/pul
sar.gif
31
(No Transcript)
32
Black Holes
  • More massive than neutron stars
  • So dense that nothing entering its gravitational
    field ever escapes, not even light!
  • The edge of a black hole, the point of no return,
    is referred to as event horizon
  • Most galaxies are now thought to have black holes
    with masses of 1.2 billion suns at their centers

Core of galaxy with accretion disk of 1.2 X 109
Msun
http//science.howstuffworks.com/black-hole3.htm
33
Summarizing It AllThe Hertzsprung-Russell (HR)
Diagram
More luminous
Cooler but much brighter means these are much
bigger
Sun
Hotter but very tiny
dim
blue
red
http//www.courses.psu.edu/astro/astro010_pjm25/he
rtzsprung2.html
34
Determining the Age of a Cluster
  • All stars in a cluster are born at approximately
    the same time
  • Lifetime on main sequence depends on the mass of
    the star
  • Most massive stars move off the main sequence
    soonest
  • Look at largest stars left on main sequence to
    estimate age
Write a Comment
User Comments (0)
About PowerShow.com