1. Cosmodynamics

2. Quintessence and solution of cosmological constant problem should be related !

3. Cosmon and fundamental mass scales Assume all mass parameters are proportional to scalar field χ (GUTs, superstrings,…) Assume all mass parameters are proportional to scalar field χ (GUTs, superstrings,…) M p ~ χ, m proton ~ χ, Λ QCD ~ χ, M W ~ χ,… M p ~ χ, m proton ~ χ, Λ QCD ~ χ, M W ~ χ,… χ may evolve with time χ may evolve with time m n /M : ( almost ) constant - observation ! m n /M : ( almost ) constant - observation ! Only ratios of mass scales are observable

4. Dirac’s hypothesis The very small dimensionless numbers in physics are due to huge age of the universe. The very small dimensionless numbers in physics are due to huge age of the universe. (A) may be true for ratio of dark energy over M 4

5. Dilatation symmetry Lagrange density: Lagrange density: Dilatation symmetry for Dilatation symmetry for Conformal symmetry for δ=0 Conformal symmetry for δ=0

6. Dilatation anomaly Quantum fluctuations responsible for Quantum fluctuations responsible for dilatation anomaly dilatation anomaly Running couplings: Running couplings: V~χ 4-A, M p (χ )~ χ V~χ 4-A, M p (χ )~ χ V/M p 4 ~ χ -A : decreases for increasing χ !! V/M p 4 ~ χ -A : decreases for increasing χ !! E>0 : crossover quintessence E>0 : crossover quintessence

7. Cosmology Cosmology : χ increases with time ! ( due to coupling of χ to curvature scalar ) “ late time cosmology explores the ultraviolet” “ late time cosmology explores the ultraviolet” for large χ the ratio V/M 4 decreases to zero Effective cosmological constant vanishes asymptotically for large t !

8. Weyl scaling Weyl scaling : g μν → (M/χ) 2 g μν, φ/M = ln (χ 4 /V(χ)) φ/M = ln (χ 4 /V(χ)) Exponential potential : V = M 4 exp(-φ/M) No additional constant !

9. Crossover Quintessence ( like QCD gauge coupling) ( like QCD gauge coupling) critical χ where δ grows large critical φ where k grows large k²(φ )=δ(χ)/4 k²(φ )= “1/(2E(φ c – φ)/M)” k²(φ )= “1/(2E(φ c – φ)/M)” if  c  ≈ 276/M ( tuning ! ) if  c  ≈ 276/M ( tuning ! ) Relative increase of dark energy in present Relative increase of dark energy in present cosmological epoch cosmological epoch

13. “Fundamental” Interactions Strong, electromagnetic, weak interactions gravitationcosmodynamics On astronomical length scales: graviton + cosmon

14. Cosmon Tiny mass Tiny mass m c ~ H m c ~ H New long - range interaction New long - range interaction

15. cosmon mass for standard kinetic term for standard kinetic term m c 2 = V” m c 2 = V” for standard exponential potential, k = const. for standard exponential potential, k = const. m c 2 = V”/ k 2 = V/( k 2 M 2 ) m c 2 = V”/ k 2 = V/( k 2 M 2 ) = 3 Ω h (1 - w h ) H 2 /( 2 k 2 ) = 3 Ω h (1 - w h ) H 2 /( 2 k 2 )

16. Are fundamental “constants” time dependent ? Fine structure constant α (electric charge) Ratio nucleon mass to Planck mass

17. “Fifth Force” Mediated by scalar field Mediated by scalar field Coupling strength: weaker than gravity Coupling strength: weaker than gravity ( nonrenormalizable interactions ~ M -2 ) ( nonrenormalizable interactions ~ M -2 ) Composition dependence Composition dependence violation of equivalence principle violation of equivalence principle Quintessence: connected to time variation of Quintessence: connected to time variation of fundamental couplings fundamental couplings R.Peccei,J.Sola,C.Wetterich,Phys.Lett.B195,183(1987) C.Wetterich, Nucl.Phys.B302,645(1988)

18. Quintessence and Time dependence of “fundamental constants” Fine structure constant depends on value of Fine structure constant depends on value of cosmon field : α(φ) cosmon field : α(φ) (similar in standard model: couplings depend on value of Higgs scalar field) (similar in standard model: couplings depend on value of Higgs scalar field) Time evolution of φ Time evolution of φ Time evolution of α Time evolution of α Jordan,…

19. Field dependent gauge coupling ( gauge invariance maintained ) for GUT : C.Hill ; Q.Shafi, CW

20. GUT : running of electromagnetic and strong gauge coupling related strong effect from variation of nucleon mass for time dependent couplings ! X.Calmet, H.Fritzsch

21. Variation of fine structure constant as function of redshift Webb et al Srianand et al

22. Variation of fine structure constant Three independent data sets from Keck/HIRES Three independent data sets from Keck/HIRES Δ α/α = - 0.54 (12) 10 -5 Δ α/α = - 0.54 (12) 10 -5 Murphy,Webb,Flammbaum, june 2003 Murphy,Webb,Flammbaum, june 2003 VLT VLT Δ α/α = - 0.06 (6) 10 -5 Δ α/α = - 0.06 (6) 10 -5 Srianand,Chand,Petitjean,Aracil, feb.2004 Srianand,Chand,Petitjean,Aracil, feb.2004 z ≈ 2

23. Crossover quintessence and time variation of fundamental “constants” Upper bounds for relative variation of the Upper bounds for relative variation of the fine structure constant fine structure constant Oklo natural reactor Δ α/α < 10 -7 z=0.13 Oklo natural reactor Δ α/α < 10 -7 z=0.13 Meteorites ( Re-decay ) Δ α/α < 3 10 -7 z=0.45 Meteorites ( Re-decay ) Δ α/α < 3 10 -7 z=0.45 Crossover Quintessence leads to small variation of couplings at low z as compared to z ≈ 2 ! Crossover Quintessence leads to small variation of couplings at low z as compared to z ≈ 2 !

24. Time evolution of fundamental couplings traces time evolution of quintessence today w h close to -1 : today w h close to -1 : Small kinetic energy Small kinetic energy Slow change of φ Slow change of φ Slow change of α Slow change of α Very small Δα/α for low z ! Very small Δα/α for low z !

25. Variation of fine structure constant as function of redshift Webb et al

26. Cosmon and time variation of couplings small coupling of cosmon to matter due to fixed points behavior small coupling of cosmon to matter due to fixed points behavior close to fixed point : small time evolution of couplings coupling to matter weaker than gravitational strength

27. dependence of fixed point on δ could induce observable effect adjusting b 6 to reproduce results by Webb et al: smaller for Srianand et al !

28. Time variation of coupling constants is tiny – would be of very high significance ! Possible signal for Quintessence

29. Παντα ρει

30. Cosmodynamics Cosmon mediates new long-range interaction Range : size of the Universe – horizon Range : size of the Universe – horizon Strength : weaker than gravity Strength : weaker than gravity photon electrodynamics photon electrodynamics graviton gravity graviton gravity cosmon cosmodynamics cosmon cosmodynamics Small correction to Newton’s law

31. Violation of equivalence principle Different couplings of cosmon to proton and neutron Differential acceleration Violation of equivalence principle earth p,n cosmon

32. Differential acceleration η For unified theories ( GUT ) : Q : time dependence of other parameters η=Δa/2a

33. Link between time variation of α and violation of equivalence principle typically : η = 10 -14 if time variation of α near Oklo upper bound to be tested by MICROSCOPE

36. This leads to differential acceleration !

37. Atomic clocks and OKLO assumes that both effects are dominated by change of fine structure constant

38. small change of couplings in space

39. Summary o Ω h = 0.7 o Q/Λ : dynamical und static dark energy will be distinguishable will be distinguishable o Q : time varying fundamental coupling “constants” violation of equivalence principle violation of equivalence principle

40. ???????????????????????? Why becomes Quintessence dominant in the present cosmological epoch ? Are dark energy and dark matter related ? Can Quintessence be explained in a fundamental unified theory ?

41. Cosmon dark matter

50. end ?