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Lec 8 What have we learned: [chpt 11.4] –Conditions of gravitational collapse (=growth) –Stable oscillation (no collapse) within sound horizon if pressure-dominated.

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Presentation on theme: "Lec 8 What have we learned: [chpt 11.4] –Conditions of gravitational collapse (=growth) –Stable oscillation (no collapse) within sound horizon if pressure-dominated."— Presentation transcript:

1 Lec 8 What have we learned: [chpt 11.4] –Conditions of gravitational collapse (=growth) –Stable oscillation (no collapse) within sound horizon if pressure-dominated Where are we heading: –Cosmic Microwave Background [chpt 15.4] As an application of Jeans instability –Inflation in the Early Universe [chpt 20.3]

2 Theory of CMB Fluctuations Linear theory of structure growth predicts that the perturbations: will follow the following coupled equations. Or

3 Where  is the perturbation in the gravitational potential, with Gravitational Coupling

4 Each eq. is similar to a forced spring F m Term due to friction (Displacement for Harmonic Oscillator) x t Restoring

5 The solution of the Harmonic Oscillator [within sound horizon] is: Amplitude is sinusoidal function of k c s t –if k=constant and oscillate with t –or t=constant and oscillate with k. For B or R

6 We don’t observe directly-what we actually observe is temperature fluctuations. The driving force is due to dark matter over densities. The observed temperature is: Effect due to having to climb out of graviatational well

7 The observed temperature also depends on how fast the Baryon Fluid is moving. Doppler Term

8 Inflation in Early Universe [chtp 20.3] Problems with normal expansion theory: –What is the state of the universe at t  0? Pure E&M field (radiation) or exotic scalar field? –Why is the initial universe so precisely flat? –What makes the universe homogeneous/similar in opposite directions of horizon? Solutions: –Maybe the horizon can be pushed to infinity? –Maybe there is no horizon? –Maybe everything was in Causal contact at early times?

9 x sun x Horizon Why these two galaxies so similar without communicating yet? Why curvature term so small (universe so flat) at early universe if radiation dominates n=4 >2?

10 What have we learned? What determines the patterns of CMB at last scattering –Analogy as patterns of fine sands on a drum at last hit. The need for inflation to –Bring different regions in contact –Create a flat universe naturally.

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