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+ Quintessence and Gravitational Waves Peng Zhou, Daniel Chung UW-Madison Physics Dept.

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Presentation on theme: "+ Quintessence and Gravitational Waves Peng Zhou, Daniel Chung UW-Madison Physics Dept."— Presentation transcript:

1 + Quintessence and Gravitational Waves Peng Zhou, Daniel Chung UW-Madison Physics Dept

2 + Gravitational waves Linearized wave equation GW couples to matter weakly Propagate freely Hard to detect Sources of GW (coordinated motion of huge mass) Binary rotating stars, supernovae… First order phase transition (e.g. elelctroweak PT), by bubble collision and turbulence If some unknown energy exist during EWPT, how would the GW spectrum change?

3 + Quintessence Courtesy to Scott Dodelson’s Modern Cosmology Quintessence Dark Energy could be… Static?Cosmological constant :  Dynamic? Quintessence Quintessence Scalar field Couples to matter by gravity If kination domination[1] Dilutes faster Dominate in the past [1] Daniel J.H. Chung et. al. Connecting LHC, ILC, and Quintessence. JHEP 0710:016,2007.

4 + Literature review: Bubble Collision How to describe bubble nucleation? Universe cools down -> nucleation start -> nucleate faster and faster as T drops How to describe one bubble’s growth[1]? Bubble wall velocity Interior fluid motion and temperature How to describe two bubbles collision? Simulation[2]: Thin-wall approximation, envelope approximation Analytic method[3]: velocity correlator  stress tensor correlator  GW’s energy tensor [1] Paul Steinhardt, Relativistic Detonation waves and bubble growth in false vacuum decay. PRD V25 #8 [2] Kamionkowski, Arthur Kosowsky, Michael S. Turner, Gravitational radiation from first order phase transitions. Phys.Rev.D49:2837- 2851,1994 [3] Chiara Caprini, Ruth Durrer, Geraldine Servant Gravitational wave generation from bubble collisions in first-order phase transitions: An analytic approach Phys.Rev.D77:124015,2008. Chiara Caprini Ruth DurrerGeraldine Servant

5 + Literature review: Turbulence With quadrupole approximation for GW generation and dimension analysis for turbulence, Kamionkowski et al[1] derived: An analytic approach by Durrer et al[2], velocity correlator  stress tensor correlator ~ Turbulence: superposition of big and small eddies. 1.Energy injection scale 2.Energy dissipation scale 3.Energy dissipation rate Velocity of eddy of size l: [1]Kamionkowski, Arthur Kosowsky, Michael S. Turner, Gravitational radiation from first order phase transitions. Phys.Rev.D49:2837-2851,1994 [2]Chiara Caprini, Ruth Durrer Gravitational waves from stochastic relativistic sources: Primordial turbulence and magnetic fields. Phys.Rev.D74:063521,2006.

6 + Not sure yet.. Bubble wall velocity uncertainty due to friction (G. Moore[1]) Once the plasma inside th e bubble gains mass, it will slow down the bubble wall velocity, breaks down the detonation scenario. The predicted GW spectrum is only firm in the large scale region(small k region), where the sources are evenly distributed. Regarding the peak position and the small distance region, it is still under investigation[2]. Our result is a general statement, not sensitive to these uncertainties. [1]G.Moore Electroweak bubble wall friction: Analytic results. JHEP 0003:006,2000. hep-ph/0001274 [2] Chiara Caprini, Ruth Durrer, Thomas Konstandin, Geraldine Servant, General Properties of the Gravitational Wave Spectrum from Phase Transitions. arXiv:0901.1661 [astro-ph]

7 + Research Method Identify all the factors affecting the GW spectrum, i.e. the parametric dependence of the spectrum. And find out the key factor controlling the spectrum’s peak, amplitude and shape. Find out how the addition of quintessence will change these parameters and the subsequently the spectrum.

8 + Bubble Collision Assume only one scale exist, the duration of PT All uncertainties resides is here

9 +

10 + Turbulence comparable contribution as bubble collision Same parametric dependence on Hubble expansion rate. Turbulence has a new scale, the dissipation scale, but it only affect the GW spectrum’s cut-off frequency. So previous conclusion still holds. Detonation (from Durrer’s model) Turbulence(from Durrer’s model)

11 + Interaction between bubbles So far we have approximating No interaction between bubble before they collide Only true for vacuum case, when bubble wall velocity=c If we consider interaction between bubble walls exchange Z boson would give the dominant contribution. But that contribution to stress tensor turns out to be negligible compared with bubble wall’s stress tensor.

12 + Our result Parametrize the quintessence’s amplitude and evolution behavior as

13 + Summary The addition of quintessence will not alter the plasma’s energy density, pressure or temperature. Quintessence will accelerate the expansion rate of universe then, make the universe cool down faster, thus shortening the phase transition duration Quintessence will shift the peak of the spectrum and lower the amplitude according to

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