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Lecture 3: Modified matter models of dark energy

Lecture 3: Modified matter models of dark energy. Shinji Tsujikawa (Tokyo University of Science). What is the origin of dark energy?. The simplest candidate: Cosmological constant. However this suffers from a fine-tuning problem if it originates from a vacuum energy.

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Lecture 3: Modified matter models of dark energy

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  1. Lecture 3:Modified matter models of dark energy Shinji Tsujikawa (Tokyo University of Science)

  2. What is the origin of dark energy? • The simplest candidate: Cosmological constant However this suffers from a fine-tuning problem if it originates from a vacuum energy. • Dynamical dark energy models Quintessence, k-essence, chaplygin gas, tachyon, f (R) gravity, scalar-tensor theories, Braneworld, Galileon, …

  3. Cosmological constant: Originally introduced by Einstein to realize the static Universe. 1998 (119 old:heaven) 1917 (38 old) 1945 (66 old) In 1929 Hubble found the expansion of the Universe. ‘Biggest Blunder in my life’ Static Universe Big Bang cosmology+ cosmic acceleration Big Bang Cosmology

  4. Cosmological constant problem or, Cosmo-illogical constant problem (by Rocky Kolb) The energy scale of dark energy today is If we take the Planck scale as a cut-off scale, the energy scale of the vacuum energy is Problem even before 1998 See my review in 1989. by Steven Weinberg

  5. The cosmological constant is (i) sufficiently small to explain the energy scale of dark energy? (ii) or, completely zero? Case (i): Both the cosmological constant and the dark energy problems are solved at the same time. Economical Case (ii): The cosmological constant problem is solved, but the dark energy problem has to be addressed. This possibility remains. `Modified matter’ (such as a scalar field) is introduced, or gravity is modified from Einstein gravity (Dynamical dark energy).

  6. Example of case (i): de-Sitter vacua in string theory Kachru-Kallosh-Linde-Trivedi (KKLT) scenario Type II string theory compactified on a Calabi Yau manifold with a flux. The KKLT scenario consists of three steps. Potential: where

  7. We add uplifting potential generated by anti-D3 brane at the tip of warped throat: The total potential is It is possible to explain dark energy if dS uplifting AdS

  8. String Landscape We may live in a vacuum with a small energy density (related with anthropic selection). 500 10 uplifted vacua!

  9. Example of case (ii) [vanishing cosmological constant] In supersymmetric theories the vacuum energy is zero if supersymmetry is unbroken, but in real word supersymmetry is broken. K: Kahler potential W: Superpotential _________________ ______ Cancellation is required

  10. Dynamical dark energy models We can classify the models into two classes. (Einstein equation) (i) Modified gravity (ii) Modified matter f(R) gravity, Scalar-tensor theory, Braneworlds, Gauss-Bonnet gravity, Galileon gravity, ….. Quintessence, K-essence, Chaplygin gas, Coupled dark energy, (including mass varying neutrinos) …..

  11. Modified matter models based on scalar fields • Quintessence (‘fifth element’): Accelerated expansion based on the potential energy ‘X matter’ Chiba, Sugiyama, Nakamura (1997) ‘Quintessence’ Caldwell, Dave, Steinhardt (1998) • K-essence: where Accelerated expansion based on the kinetic energy Chiba, Okabe, Yamaguchi (1999) ‘Kinetically driven quintessence’ Armendariz-Picon, Mukhanov, Steinhardt (2000) ‘k-essence’

  12. Quintessence: French wine! _____________________________

  13. Potentials of Quintessence Energy density: Pressure: Equation of state for Quintessence phantom Quintessence Quintessence can be distinguished from the LCDM. As long as the potential is sufficiently flat, cosmic acceleration can be realized.

  14. Particle physics models of quintessence (i) Fermion condensate in globally supersymmetric QCD theories (Binetruy) The inverse power-law potential was derived. where (ii) Supergravity models (Brax and Martin, Copeland et al) The field potential in SUGRA theories is

  15. (iii) Pseudo-Nambu Goldston Boson (PNGB) models (Friemann et al) The filed starts to evolve only recently.

  16. Classification of Quintessence potentials (Caldwell and Linder, 2003) (A) Freezing models: Example Since the potential tends to be flatter, the evolution of the field slows down. . (B) Thawing models: Example . The field has been nearly frozen in the past, but it starts to evolve around today

  17. Quintessence in the (w,w’) plane The current observations are not still enough to find the evidence for the variation of the equation of state. . LCDM

  18. Dynamical system approach to quintessence

  19. Dynamical equations The fixed point responsible for the cosmic acceleration is

  20. Phase space Attractor (cosmic acceleration) Saddle (matter point)

  21. General potentials where (tracking condition) Tracking always occurs.

  22. Numerical simulations for

  23. K-essence K-essence is described by the action where The models that belong to k-essence is Conformal transformation or

  24. Equation of state for k-essence

  25. Stability condition for k-essence

  26. Some people tried to solve the coincidence problem of dark energy by considering a specific Lagrangian Armendariz-Picon, Mukhanov, Steinhardt (2000) • However it is difficult to construct such models theoretically. • Moreover they typically have the superluminal propagation speed. k-essence density parameter

  27. Chaplygin gas model Chaplygin gas Generalized Chaplygin gas This corresponds to unified dark energy models in which dark matter and dark energy are explained as a single component. (pressureless matter) (dark energy) Continuity equation:

  28. Past: Future:

  29. Chaplygin gas satisfies observational constrants ? No! _________________ ____ The sound speed term prevents the growth of large-scale structure. Observational constraints This cannot be distinguished from the LCDM. Matter power spectrum

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