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What do you think of when you look at the night sky?. http://www.astro.ufl.edu/~lada/ast3018/lectures/ast3018lecturestarform.pdf. What is Space?. Not really empty Stars, planets, etc. Interstellar medium Dust and Gas Nebulas. Orion Nebula
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What do you think of when you look at the night sky? http://www.astro.ufl.edu/~lada/ast3018/lectures/ast3018lecturestarform.pdf
What is Space? • Not really empty • Stars, planets, etc. • Interstellar medium • Dust and Gas • Nebulas Orion Nebula http://hubblesite.org/gallery/album/nebula/pr1995044a/ Large Magellanic Cloud http://hubblesite.org/gallery/album/nebula/pr2006055a/
Nebular Hypothesis • Random collisions of atoms • Areas of growing mass • Spherical shape • Pull in more matter • Increase in • Temperature • Pressure • Spin • Creates a bulge in the sphere http://physics.uoregon.edu/~jimbrau/BrauImNew/Chap06/FG06_17.jpg
Nuclear Fusion • High temperatures • 2 particles become 1 • Releases a lot of energy • Video clip • Particle accelerators • Man-made • Create new elements • Find smallest particles http://www.universetoday.com/52696/nuclear-fusion-power-closer-to-reality-say-two-separate-teams/ Fermi National Lab http://www.wired.com/playbook/2012/08/olympics-physics-hammer-throw/
Spectroscopy Activity • Draw the lines that you see • Make sure the # of lines, color of the lines and order is accurate • Write a conclusion – based on your observations what can you conclude about the different materials and light you see the material produce
Warm Up #1 • Clicker Quiz • Compare conclusions from the spectroscopy activity
What does a spectrum tell us? • Each chemical/atom has a unique spectrum • Like a fingerprint • What chemicals are present http://www.umsl.edu/~physics/Lab%20Connection/Electricity%20and%20Magnetism%20Lab/12-lab13.html
How is a spectrum created? • All objects emit light • Pure light from a source • Continuous spectrum • If light passes through gas or dust • Light absorbed • Excites/heats atoms • Emit own light • Makes an emission spectrum • Unique https://www.cfa.harvard.edu/~jbattat/a35/cont_abs_em.html
How do astronomers use spectra? • Look at light from • Stars (gas in outer layers) • Nebula • Planets • Determine chemical composition • Can also determine movement of object • Activity http://www.eso.org/public/outreach/eduoff/cas/cas2004/casreports-2004/rep-236/
Warm Up #2 • Why are emission spectra important? • How are emission spectrum created? • What 2 things can astronomers learn by looking at the spectrum from a star?
H-R Diagram Graphing Activity • Look for patterns http://www.rootstown.sparcc.org/mattjust/h-r-diagram
Color and Temperature • What did you see as a pattern? • Objects give off a variety of light • Peak depends on temperature • Peak shows most common type of light http://docs.kde.org/stable/en/kdeedu/kstars/ai-colorandtemp.html
Main Sequence Stars • Find group on H-R diagram • Wide variety • Highest # of stars • Stars stay here the longest • Actively fusing hydrogen into helium • Outward pressure from fusion • Inward pressure from gravity • Equal in these stars • Maintain size http://www.thenakedscientists.com/HTML/articles/article/the-science-of-the-supernova/ http://www.rootstown.sparcc.org/mattjust/h-r-diagram
What happens to our Sun? • Form red giants • Fusing helium • Core collapsing • Outer layers spread out • Cools http://flightline.highline.edu/iglozman/classes/astronotes/media/2paths.jpg http://www.physics.uc.edu/~hanson/ASTRO/LECTURENOTES/StarLife/Page7.html
What then? • Forms a white dwarf • Ran out of helium • No more fusion • Outer gasses moving away • Planetary nebula • Leaves a hot, dense core http://chandra.harvard.edu/xray_sources/white_dwarfs.html Ring Nebula http://hubblesite.org/gallery/album/nebula/planetary/pr2004032d/ Cat’s Eye Nebula http://hubblesite.org/gallery/album/nebula/planetary/pr2004027a/
Warm Up #3 • What makes a star a main sequence star? • Why does the size of the core of a main sequence star not change? • What will eventually happen to our Sun and why?
What about the fate of larger stars? • Become red supergiants • Fuse elements larger than helium • All the way to iron • Short lives • Supernova • No more fusion • Core violently explodes • Fuses heavier atoms • Very bright, short time • Spreads out material http://flightline.highline.edu/iglozman/classes/astronotes/media/2paths.jpg http://hubblesite.org/gallery/album/nebula/supernova_remnant/pr2005037a/
What then? • Forms a neutron star • If a lower mass core • Very dense • Not very big • Lots of gravity • Can produce gamma and x-rays when it pulls items into it Neutron star in supernova Cassiopeia A http://www.space-pictures.com/view/pictures-of-space/pictures-of-stars/neutron-star/index.php http://www.clccharter.org/maya1/Supernova/supernova.html
Or… • Forms a black hole • Higher mass cores • Infinitely dense • Need to travel faster than the speed of light to escape • How can we see? • Will bend light from nearby stars • See dust and gas swirling around • Hot enough to give off x-rays • Probably at the center of most galaxies • Including ours! • Video http://www.space.com/15421-black-holes-facts-formation-discovery-sdcmp.html Whirlpool Galaxy http://hubblesite.org/gallery/album/pr2001010a/
Warm Up #4 • What is happening inside a red supergiant star? • What happens in a supernova? • How is a neutron star different from a black hole? • Why should we not be able to see a black hole? • Why can we “see” a black hole?
Warm Up #5 • Clicker Quiz
How do we know how far away that is? • Parallax effect • Compare distant stars to nearby stars • Measure shift as Earth orbits the Sun • Calculate the distance • Further away = less of a shift • Better technology = see smaller shifts = measure larger distances http://lifeng.lamost.org/courses/astrotoday/CHAISSON/AT301/HTML/AT30105.HTM
Looking Back in Time • If a star is 10 light years away • How old is the light we see today? • Is that star still there today? • If an alien is on a planet 10 million light years away • If they could see with the Earth with great detail, what would they see right now? • When we observe light from a star 2 billion light years away….what does that mean? http://www.spacetelescope.org/images/heic1214c/
How has our “picture” of the universe changed? • Greeks • Rotating spheres • Earth centered
Early Scientists • Galileo • Copernicus • Kepler • Newton • Mathematical laws about movement of planets • First telescope • Calculation of gravity • Sun centered universe
Next generation of scientists… • Einstein • Calculations • Universe changing size • Disbelieved • Added a constant to his equations • Results = static universe • Friedmann • Russian • Removed Einstein’s constant • Universe changing shape • Won Einstein’s approval http://wouterdeheij.wordpress.com/2013/04/27/famous-innovation-quotes-from-steve-jobs-gunter-pauli-einstein-henry-ford-and-many-others/ http://en.wikipedia.org/wiki/File:Aleksandr_Fridman.png
The Big Bang Theory • Lemaitre • Priest and physicist • Universe began as a single point • Expanded since that time • Hubble • Astronomer • Published around same time • Provided evidence http://scienceblogs.com/startswithabang/2011/01/05/q-a-how-is-the-universe-so-big/
Hubble’s Evidence - Redshift • Change in emission spectrum • Same pattern • Shifted from where it should be
Same thing happens with sound… • Doppler effect • Object moving past a stationary object • Waves get shortened in front • Higher pitch • Waves get longer in back • Lower pitch • Inside the source – no change
Relating back to light… • Blue-shift • Wavelength shortens • Moving towards us • Red-shift • Wavelength lengthens • Moving away from us • Bigger the shift the further away it has come from • Hubble only saw red-shifted spectra http://archive.ncsa.illinois.edu/Cyberia/Bima/doppler.html
Hubble’s Conclusions • Universe moving away from us • Things further away are moving away faster • Expansion rate has since beginning https://www.e-education.psu.edu/astro801/book/export/html/1967
The Big Bang • Started as a single point • Expansion • Explosive at first • Evidence • Red-shift
Cosmic Microwave Background Radiation • Further evidence of the big bang • Picture = • Universe all same temp • Very cold • Not what we actually see • Where else could the microwaves come from? • Extreme red-shift • From a high energy wave • Travel long distances • Oldest light we observe • Time when universe was all the same temp. • The Big Bang
Age of the Universe • Rocks on Earth • 4.2 billion years • Oldest stars • 10-12 billion years • Universe must be older • Estimate backwards • 13.8 billion years http://www.universeadventure.org/big_bang/conseq-ageofuniv.htm http://scienceblogs.com/startswithabang/2009/07/31/the-size-of-the-universe-a-har/
What happens next? • Big Crush • Stops expanding • Gravity causes to crush • Repeat the process • Big Chill • Expand at slowing rate • Get cooler as expands • Big Rip • Expand at increasing rate • Everything gets ripped apart http://sandeepdmisra.wordpress.com/2011/04/ http://ffden-2.phys.uaf.edu/212_fall2003.web.dir/eli_sonafrank/Expansion_-_Fate_of%23168EE9.html
What else is out there? • Visible matter • Dark matter • Does not give off light • Things weigh more than they should • Dark energy • Causing the increase in expansion rate seen in most recent data • Thus fate of the universe is… • Big Rip • Adding these items makes models better fit actual observations http://hubblesite.org/hubble_discoveries/dark_energy/de-what_is_dark_energy.php
What helps us understand space? • Telescopes • All wavelengths of light • Actual samples from space • Particle accelerators
Review #7 • Describe how the Doppler effect and redshift are similar, • What are the two pieces of evidence that support the Big Bang theory? • Who first wrote the Big Bang theory? • How old is the universe? • What is the current theory of the fate of the universe? • What are dark matter and dark energy? • What items are used to help us understand distant objects in space?