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1 Jason Dekdebrun Theoretical Physics Institute, UvA Advised by Kostas Skenderis TexPoint fonts used in EMF. Read the TexPoint manual before you delete this box.: A AA A A

2 Introduction  Gives answers to some of the earliest moments of our history.  Proposed by Alan Guth in 1980.  Universe undergoes an early, exponential expansion.  Solves many of the BIG problems plaguing cosmology.

3 What Quantifies Inflation?  Friedmann-Robertson-Walker (FRW) metric for a flat universe:  Inflation when:

4 Why Does Inflation Occur?  Occurs when the energy density of the universe is constant:

5 Horizon Problem ° °° ° 10 billion years 20 billion years total, Cosmic Microwave Background Observer ? BUT universe is only 14 billion years old!!!

6 Inflation Answer  H = ®, constant in time.  (aH ) -1 = ® -1 e - ® t, decreases with time!  During inflation, sphere of causal contact decreases with time. Objects that are in causal contact soon come out of causal contact.

7 Sphere Of Causal Contact Not In Causal Contact Causal Contact!

8 My Research: The Standard Scenario  A single scalar field, the inflaton .  Background FRW space-time.  During inflation, V(  ) dominates the universe.  The inflaton slowly rolls down its potential, causing inflation.

9 Slow-Roll Scenario α βδ€ζΩΣπ Important Point!: Cosmic Microwave Background is NOT from Big Bang!

10 Perturbations  In the case of the inflaton, perturbations are considered quantum fluctuations:

11  Perturbations added to the FRW metric:  This leads to perturbed general relativity quantities (Einstein tensor, Christoffels, Ricci tensor, etc.)

12 Example:

13 Equations To Solve  We would like to solve Einstein’s equations,  where the energy-momentum tensor,  is derived from the Lagrangian:

14 Example: Second Order (i,j) Einstein Equation

15  Also the Klein-Gordon equation:  This is derived from an action using the same Lagrangian.

16 Example: Second Order Klein-Gordon Equation

17 Gauge Invariant Variables  Under a spatial translation by d i, the following perturbations transform as:  Combining these in just the right way leads to a variable with no transformation:

18  3 more gauge invariant variables:  First order Einstein equations:

19  Second Order Curvature Perturbation:  This gauge invariant variable will be the link between theory and observation.

20 f NL & Observations  What is f NL ?  f NL is the amplitude of the three-point correlation function.  Correlation of curvature perturbations, ³ (2).  Also known as the bispectrum.  Any detection of the bispectrum indicates non- Gaussianity.

21 Planck Satellite  Launched May 14 th, 2009.  Finish collecting data in 2012.  Will provide very important measurements of non-Gaussianity.

22 Conclusion  Measurements of non-Gaussianity will help distinguish amongst the many different models of inflation.  This will give us a closer look and deeper understanding of the very beginning of our universe!


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