1 / 15

The Expanding Universe

The Expanding Universe. If everything is moving away from us, then in the past everything was a lot closer. Density was greater; pressure was greater. Temperature was higher. Sometime in the past, it was very small and HOT!.

gamada
Télécharger la présentation

The Expanding Universe

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. The Expanding Universe If everything is moving away from us, then in the past everything was a lot closer. Density was greater; pressure was greater. Temperature was higher. Sometime in the past, it was very small and HOT! Conclusion: There should be residual radiation left over from this dense hot period.

  2. What Should Light from This Period Look Like? Energy density per unit wave length Black-body Spectrum: Red-Shift Energy density change At detection: Temperature goes down with expansion. System stays in equilibrium

  3. Cosmic Microwave Background Test of the Big Bang Model Peebles (and others): If the universe had a very hot early phase, then the radiation from the phase should still be present today. That radiation will be red shifted by the red shift factor z=Rthen/Rnow-1. Discovery: 1964 Penzias and Wilson Bell Labs Nobel Prize, 1978

  4. T=2.725+/-.002o K COBE Satellite

  5. COBE Fluctuations Dipole Movement – Earth through Microwave background Remnant Milky Wave light Background Fluctuations 1 part in 100000.

  6. Boomerang Measurements South Pole Measurement Colors represent microwave intensity

  7. Boomerang Measurements Intensity Legendre polynomial l

  8. Big Bang Model Universe started as a hot dense medium in quasi-thermo equilibrium and expanded under the laws of physics to our present universe. Implications: Galaxies are receding. Microwave background -- measure of the universe at an age of 700,000 years (present age ~1/H0 ~ 14 billion years). Are there other clues?

  9. Temperature as a Function of Time Example: Flat Mass Dominated Universe Energy Density: Temperature: Decrease time from big ban by a factor of 10, temperature goes up by a factor of 100.

  10. Time Temperature 14 billion years 2.3o K Today 700 Million years 920o K 6.4 Red Shift Objects Atoms form Microwave Background 700,000 years 3500o K=.3 eV 200 sec 100 keV Break up Nuclei 10 sec 300 keV Electrons and Positrons Neutrinos interact with nuclei 1 sec 1 MeV 10 msec 300 MeV m, p strong interactions 100 nsec 3 GeV t, charm quark 100 psec 300 GeV Produce W, Z, t quark Timeline from Big Bang

  11. Time Temperature 14 billion years 2.3o K Today 700 Million years 920o K 6.4 Red Shift Objects Atoms form Microwave Background 700,000 years 3500o K=.3 eV 200 sec 100 keV Break up Nuclei 10 sec 300 keV Electrons and Positrons Neutrinos interact with nuclei 1 sec 1 MeV 10 msec 300 MeV m, p strong interactions 100 nsec 3 GeV t, charm quark 100 psec 300 GeV Produce W, Z, t quark Timeline from Big Bang D/H ratio Light Elements

  12. Big Bang Nucleosynthesis Competition: Other reaction: Exact ratios are determined by cooling rate which depends on baryon density.

  13. Baryon Density Measurements All measurements consistent with one baryon density

  14. Time Temperature 14 billion years 2.3o K Today 700 Million years 920o K 6.4 Red Shift Objects Atoms form Microwave Background 700,000 years 3500o K=.3 eV 200 sec 100 keV Break up Nuclei 10 sec 300 keV Electrons and Positrons Neutrinos interact with nuclei 1 sec 1 MeV 10 msec 300 MeV m, p strong interactions 100 nsec 3 GeV t, charm quark 100 psec 300 GeV Produce W, Z, t quark Timeline from Big Bang HEP predictions

  15. And What Before That? ????

More Related