The Cosmic Microwave Background

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The Cosmic Microwave Background The Cosmic Microwave Background Key Concepts 1) The universe is filled with a Cosmic Microwave Background (CMB). 2) The microwave radiation that fills the universe is nearly isotropic. 3) The microwave radiation that fills the universe has a blackbody spectrum. Evidence in favor of the Big Bang theory: 4) The temperature of the CMB was decreased by the expansion of the universe. 5) The CMB is slightly hotter in the direction of the Earth s motion through space. 6) The CMB has warm and cool spots because of density fluctuations in the early universe. 1) The night sky is dark. Implication: the universe is of finite age; light from distant galaxies hasn t reached us. 2) Galaxies show a redshift proportional to their distance. 3) The universe is filled with a Cosmic Microwave Background (CMB). Implication: space is expanding; light from farther galaxies is stretched more. 1

Intensity Intensity The CMB has highest redshift of anything we can see (redshift z 1000). Cosmic Microwave Background = light left over from early, hot, dense, opaque universe. When we look at the CMB, we look at the surface of the glowing fog that filled the early universe! Universe became transparent when the Universes was smaller by a factor of 1000. time was t 400,000 years. Since then, CMB photons have been zooming through transparent space, changed only by being expanded in wavelength. When we observe the CMB, we see a message direct from the early universe. The universe (mostly transparent) is filled with nearly isotropic blackbody radiation (characteristic of opaque objects). What is this message telling us? Messages are often (1) hard to observe & (2) hard to interpret. Flashback: blackbody spectra are produced by hot, dense, opaque objects. The temperature of the isotropic blackbody radiation is only 2.7 Kelvin. 21,100 F 10,300 F 4900 F very cold 2

Spectacular Confirmation The COBE results confirm and greatly strengthen the Big Bang Model: The cosmic background radiation has Perfect blackbody spectrum - as predicted Has a single temperature - as predicted Uniformly fills the Universe - as predicted Predictions of Big Bang Theory Cosmic Microwave background - found with exact black body spectrum as expected Primordial Helium - There is one He atom per 10 H atoms in the Universe - Cannot be explained by H-burning in stars - Natural consequence of nucleosynthesis in the early Universe - Another confirmation of the big bang theory But first Why doesn t the CMB cook us like a microwave oven? We ve looked at the spectrum of the CMB (it s a blackbody), now let s look at a map. Spherical Earth can be projected onto a flat map: A microwave oven at full power contains 10 18 microwave photons. The same volume of outer space contains 10 7 CMB photons. Too dilute for cooking... So can the (imaginary) celestial sphere: (visible light) Mapping the CMB (color = temperature) hotter T = 2.725 K Observation: Temperature of CMB is nearly isotropic (the same in all directions). Interpretation: early universe was nearly homogeneous (the same in all locations). cooler Observation: Temperature of CMB is slightly hotter toward Leo, cooler toward Aquarius (on opposite side of sky). Temperature fluctuation = 1 part per 1000. mk = 0.001 Kelvin 3

Interpretation: difference in temperature results from a Doppler shift. Earth orbits Sun (v 29 km/sec) Sun orbits center of the Galaxy (v 220 km/sec) Galaxy falls toward Andromeda Galaxy (v 50 km/sec) Local Group falls toward Virgo Cluster (v 200 km/sec) redshifted (Aquarius) Net motion: toward Leo, with a speed v 300 km/sec 0.001 c. blueshifted (Leo) Cosmic light from direction of Leo is slightly blueshifted (shorter wavelength, higher temperature). The CMB is slightly hotter toward Leo because of our motion through space. Earth tugged by Sun, Sun tugged by Galaxy, Galaxy tugged by Andromeda, Local Group tugged by Virgo Cluster. All this is happening locally, right now. cooler hotter Observation: After subtracting the effect of our motion through space, CMB still shows hot & cold spots, about 1 degree across. Temperature fluctuation = 1 part per 100,000 Interpretation: observed temperature fluctuations result from density fluctuations. Observation: Hot spots in the CMB are higher in temperature than cold spots by 1 part per 100,000. Regions that were compressed had higher density, but also higher temperature (gases heat up as they are compressed). Implication: the density fluctuations in the early universe were also small (about 1 part per 100,000). 4

Why do we care about such tiny density fluctuations? We think that the large-scale structure we see in the Universe today grew from these small density fluctuations. Low-amplitude density fluctuations at t 400,000 years give rise to high-amplitude fluctuations at t 13.8 billion years. The Rich Get Richer, the Poor Get Poorer. Great Oaks from Tiny Acorns Grow. A region that was slightly denser than average will eventually become much denser than average; it s compressed by its own gravity. A dense region that initially has a small mass will become more massive; its gravity attracts surrounding matter. It s possible (with a big computer) to simulate the growth of density fluctuations. then now - Make a large (imaginary) box. - Fill it with (simulated) massive particles. - Make sure particles are packed a little closer together in some places than others. -Let it evolve. redshift z=29 redshift z=0 size = 1/30 size = 1 (The size of the box grows from 1.5 Mpc to 43 Mpc.) 5

Generic result: matter distribution goes from smooth to lumpy. 1 2 3 4 The past (t 400,000 years): Hot, dense, opaque, nearly homogeneous. Now (t 13.8 billion years): Cold background light, low average density, mostly transparent, very lumpy. Groups & Clusters of Galaxies Most galaxies are found in groups & clusters Basic Properties: Groups: 3 to 30 bright galaxies Clusters: 30 to 300+ bright galaxies Sizes: 1-10 Mpc across Distant Rich Cluster (Hubble Space Telescope Image) Superclusters Clusters of Clusters Properties: Sizes up to 50 Mpc Masses of 10 15 to 10 16 M sun 90-95% empty space (voids) Often long and filamentary in shape Largest coherent structures in the Universe 6

Voids, Filaments & Walls The Universe is NOT uniformly filled with galaxies The Universe looks foamy on large scales Filaments: Vast chains of superclusters, which are clusters of clusters of galaxies Occupy ~10% of the Universe Voids: Empty bubbles 25-50 Mpc in diameter The Great Wall Implications The existence of Large Scale Structure tells us about how galaxies formed from the tiny fluctuations in the Cosmic Microwave Background (CMB) 7

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