1 / 37

Chapter 27: Stars and Galaxies

Chapter 27: Stars and Galaxies. H. Thiele Earth Science. Characteristics of Stars. Size varies from 20km to 1billion km Color varies based on temperature Mass ranges between 50X less to 50X more than our sun Our sun is an average star. Composition.

kayla
Télécharger la présentation

Chapter 27: Stars and Galaxies

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Chapter 27: Stars and Galaxies H. Thiele Earth Science

  2. Characteristics of Stars • Size varies from 20km to 1billion km • Color varies based on temperature • Mass ranges between 50X less to 50X more than our sun • Our sun is an average star

  3. Composition • Star composition observed through a spectrometer • Separates light into its individual colors • Each color represents a different wavelength • Three types of spectra • Bright-line • Dark-line • Continuous • Hydrogen is the most common element in the stars. Helium is the second most common

  4. Star Temperature and Composition

  5. Motion and Distance • Motion • Circumpolar: stars that never go below the horizon • Tracking circumpolar stars leaves a curved trail • Distance • Light Year = 9.5x1012km • Use parallax over a six-month period to determine distance • Parsec: Parallax second-A unit of distance derived from the measurement of stellar distances by parallax. One parsec is equivalent to roughly 3¼ light years. • Cepheid Variables: Brighten and fade at regular intervals

  6. Circumpolar Stars

  7. Light Years Because a light year is directly related to the time light takes to travel through space, it follows that we look out into the universe we also look back in time. For example, in about the year 5,350 BC, a star in the constellation of Taurus exploded. That star was about 6,300 light years from Earth, meaning that the light from the explosion took 6,300 years to cross the intervening space, and finally reached us in the year AD 1054; that was the date Earthbound observers finally saw the explosion that created the Crab Nebula. This 'lag' is a consequence of the immense distances between the stars - when we look up at the Crab Nebula today, we see it not as it is now, but as it was in about 4,300 BC.

  8. Stellar Magnitude • Magnitude: a way to measure the brightness of a body in the sky • Absolute: the true brightness of the object • Would line up the stars all 10 parsecs from the earth • Abbreviated: M • Apparent: the brightness as seen from earth • Difference between a 1 and a 5 is 100x • Brightest star, Sirius, -1.46 • Brightest planet, Venus, -4.6 • Brightest in night sky, moon, -12.5 • Brightest in the sky, Sun, -26.8

  9. Magnitudes Apparent Magnitude Scale

  10. Stellar Evolution Nebula Heavyweight Lightweight

  11. Nebula a cloud of interstellar gas and dust. Though they can exist in many forms, nebulae tend to be associated with the beginnings and endings of stars. Nebulae form the raw material for the formation of stars, but are also created by material 'cast off' by stars in their final stages of life.

  12. Protostars The earliest stage in a star's development. A protostar represents a region in which the density of the interstellar medium is increasing due to gravitational effects, and in the process of collapsing to form a true star

  13. Fusion • A star is born when fusion begins H + H  He • Fusion is a reaction when two small nuclei come together to form larger nuclei • The result is the release of a large amount of energy

  14. Main Sequence Star • Composed mainly of Hydrogen • The fusion reactions in its core releases enormous amounts of energy and forms the element helium • A star in this phase of its life, when it belongs to the 'main sequence', runs on hydrogen 'fuel', which it will eventually convert entirely into helium. • The lifetime of a main sequence star is heavily dependent on its mass. • Our own Sun - a fairly typical main sequence star - has been burning hydrogen for about 5,000 million years, and will probably continue to do so for another 5,000 million. • More massive stars, though, have much shorter lifespans, often measured in mere hundreds of millions of years.

  15. Red Giant • As the star's hydrogen supplies run out, its form changes significantly. • Its core, now composed almost entirely of helium, begins to collapse upon itself, releasing further energy. • This is sufficient to power an expansion of the matter around the decaying core, and the outer layers of the star swell to many times their original size. • Meanwhile, the collapsing helium core reaches a point where fusion can proceed once again, this time fusing atoms of helium to produce carbon and oxygen. • In this new phase, the temperature of the outer layers of the swollen star has cooled to give it a red light, and the resulting star type is known as a red giant.

  16. Red Giants Antares

  17. Planetary Nebula • When a red giant reaches the end of its life, it casts off its outer shell of matter while its core collapses into a white dwarf. • The shell expands outwards at incredible speeds forming a distinctive type of nebula the Planetary Nebula. • Planetary Nebulae can take the form of simple rings or 'bubble' shapes (like the Ring Nebula in Lyra), or more complex spiralling forms, such as that shown by the Cat's Eye Nebula in Draco.

  18. Planetary Nebula Ring Nebula Cat’s Eye Nebula

  19. Dwarfs • The decaying remnant of a star that has exhausted all available sources of nuclear fusion. They burn very hot. • White dwarfs are typically just a few times more massive than the Earth • A white dwarf has no internal energy source, and will eventually lose what energy it has, becoming completely a dead star known as a brown dwarf.

  20. White Dwarfs

  21. H-R Diagrams

  22. The Path Our Sun Will Follow

  23. Type 1 Supernova • Happens in binary star systems • Need a brown dwarf and a red giant • The brown dwarf takes gases from the red giant and undergoes fusion once again

  24. 1987A

  25. Stellar Evolution of a Massive Star

  26. Super Red Giants (Super Giants) • Work the same way as red giants, but more massive. • They grow larger, cooler, and brighter • Burn out quicker

  27. Supernova • Stars which are 5 times or more massive than our Sun end their lives in a most spectacular way; they go supernova. • A supernova explosion will occur when there is no longer enough fuel for the fusion process in the core of the star to create an outward pressure which combats the inward gravitational pull of the star's great mass. • In less than a second, the star begins the final phase of gravitational collapse. • The core temperature rises to over 100 billion degrees as the iron atoms are crushed together. • The repulsive force between the nuclei overcomes the force of gravity, and the core recoils out from the heart of the star in an explosive shock wave. • As the shock encounters material in the star's outer layers, the material is heated, fusing to form new elements and radioactive isotopes. • The shock then propels the matter out into space. The material that is exploded away from the star is now known as a supernova remnant.

  28. Neutron Stars • Neutron stars are born during supernova • A neutron star has roughly the mass of our Sun crammed in a ball ten kilometers in radius. • Its density is therefore a hundred trillion times the density of water; at that density, all the people on Earth could be fit into a teaspoon! • Because of its small size and high density, a neutron star possesses a surface gravitational field about 300,000 times that of Earth.

  29. Size of a Neutron Star

  30. Crab Nebula from Supernova of 1054AD Pulsars • Radio pulsars, the first observed in the Crab nebula in the late 1960s • Believed to be neutron stars that spin at velocities of up to 600 revolutions a second • Send a beacon of radio waves whirling across space.

  31. Black Holes • Black holes are formed when an extremely massive star dies in a supernova • black hole is a region of space in which the matter is so compact that nothing can escape from it, not even light • The "surface" of a black hole, inside of which nothing can escape, is called an event horizon. • The matter that forms a black hole is crushed out of existence

  32. Black Hole Images

  33. The Constellations

  34. What are Constellations • They are not real • They are images created by people in the past • They represent everyday objects or mythical people from ancient times • They break up the sky into parts that allow us to find our way around

  35. Is the Big Dipper a Constellation? • NO • The Big Dipper is an asterisim. • Asterisim: • Familiar groupings in the sky • Can be parts of one or many constellations • Examples: big dipper, little dipper, summer triangle, northern cross

  36. What Constellations Should I Know? • Cassiopeia • Cepheus • Cygnus • Orion • Ursa Major • Ursa Minor

  37. The End

More Related