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Dark Energy & MSSM

Dark Energy & MSSM. Jérôme Martin. Institut d’Astrophysique de Paris (IAP). Dark Energy & MSSM. Talk based on the two following papers:. “Dark Energy and the MSSM”, P. Brax & J. Martin, hep-th/0605228 “The SUGRA Quintessence Model Coupled to the MSSM”, P. Brax & J. Martin, astro-ph/0606306.

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Dark Energy & MSSM

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  1. Dark Energy & MSSM Jérôme Martin Institut d’Astrophysique de Paris (IAP)

  2. Dark Energy & MSSM Talk based on the two following papers: “Dark Energy and the MSSM”, P. Brax & J. Martin, hep-th/0605228 “The SUGRA Quintessence Model Coupled to the MSSM”, P. Brax & J. Martin, astro-ph/0606306 (preliminary results only! Still a lot to do)

  3. Outline: 1- Quintessence in brief (assuming High-Energy inputs) 2- Quintessence and the rest of the world: how the observable sector of particle physics is affected by the presence of dark energy? In SUGRA, the coupling can be entirely computed. 3- Consequences (two main effects studied so far). “No-go theorem” : difficult to reconcile cosmology with local (eg solar system) tests. 4- Conclusions.

  4. Observational Status The Universe is accelerating: If the acceleration is caused by some dark energy then, today, it represents about 70% of the critical energy density Assuming that dark energy is the cosmological constant, one faces serious problems in explaining its magnitude. Hence, it is interesting to seek for alternatives

  5. Quintessence The prototype of alternatives to the CC is a scalar field (quintessence) If the potential energy dominates, one can have negative pressure (as for inflation) 1- This allows us to study dark energy with time-dependent equation of state 2- This is not a “reverse-engineering” problem, ie give me the equation of state and I will give you the potential because we require additional properties, to be discussed in the following. 3- Since we have a microscopic model, we can consistently computed the cosmological perturbations 4- This allows us to discuss the link with high-energy physics and to play the game of model building. As we will see this is at this point that we have serious difficulties … 5- This does not solve the CC problem. Instead of explaining =0.7 of the critical energy density we are just back to  =0

  6. Electroweak scale Quintessence in brief Quintessence: scalar field dominating the today’s energy density budget of the Universe and such that its potential allows insensitivity to the initial conditions and reasonable model building. Tracking behavior SUGRA SUGRA potential: P. Brax & J. Martin, PLB 468, 40 (1999), astro-ph/9905040

  7. High energy physics & Quintessence What are the effects of the SUGRA corrections? 1- The attractor solution still exists since, for large redshifts, the vev of Q is small in comparison with the Planck mass Sugra correction 2- The exponential corrections pushes the equation of state towards -1 at small redshifts 3- The present value of the equation of state becomes “universal”, i.e. does not depend on  For Quintessence, the  -problem becomes the  -opportunity

  8. Quintessence and the rest of the world Remarks 1- So far, we have treated quintessence as if it were isolated from the rest of the world. 2- Certainly, the quintessence field has to be embedded into particle physics. 3- Clearly, this cannot be done into the standard model of particle physics. We have just seen that SUGRA plays a key role. It is therefore natural to consider the Minimal Standard SUGRA model as the relevant extension of the standard model. 4- Since SUGRA is universal, this will uniquely determine the couplings between quintessence and the rest of the world.

  9. Quintessence and the rest of the world Gravity mediated Observable sector Hidden sector SUSY mSUGRA Modification of the Quintessence potential Fifth force test, equivalence principle test etc … Quintessence sector

  10. Quintessence and the rest of the world We address the model-building question in the framework of Super-gravity. F-term D-term Fayet-Iliopoulos Even if the sectors are “independent”, supergravity will mix them and cause a universal coupling, the coupling constant being related to the Planck mass (gravity). In the mSUGRA model, this is how susy breaking is transmitted to the observable sector (“gravity mediated”)

  11. Quintessence and the rest of the world Effect 1: modification of the dark sector (“soft terms” in the dark sector). Application to the SUGRA potential (more general in fact) Quintessence potential coming from the dark sector only This term is constant if the hidden sector is stabilized. This term “encodes” our ignorance of the hidden sector. Gravitino mass= mass of the quintessence field if the hidden sector is stabilized Two cases 1- The hidden sector is stabilized, the quintessence potential acquires a minimum and a mass of the order of the gravitino mass: like a CC! 2- The hidden sector is still “complicated” and the runaway shape is preserved (concrete examples?). The mass remains tiny

  12. Quintessence and the rest of the world Effect 2: The soft terms in the observable sector becomes Q-dependent Standard potential of the MSSM The soft terms are now quintessence dependent

  13. Quintessence and the rest of the world Application to the Electro-weak transition in the MSSM There are two Higgs instead of one The EW transition is intimately linked to the breaking of SUSY Observable sector SUSY Gravity mediated Hidden sector Without the breaking of SUSY, the Higgs potential only has a global minimum. The breaking of SUSY modifies the shape of the potential through the soft terms Then, the particles acquire mass when the Higgs acquire a non- vanishing vev

  14. Quintessence and the rest of the world As a consequence, the vev’s of the Higgs become Q-dependent Completely calculable in a given model (here the SUGRA model) Yukawa couplings Main Result: The fermions pick up a Q-dependent mass which is not the same for the “u” or “d” particles. This is calculable entirely from SUGRA.

  15. Quintessence and the rest of the world Consequences: “u particle” “d particle” Through redefinitions, this type of theory can be put under the form of a scalar-tensor theory

  16. Quintessence and the rest of the world This type of theory is constrained by various gravity experiments. In practice, one has constraints on the function A and its derivatives, namely Two cases: 1- The mass of the field Q is larger than 10-3 eV (the range is smaller than the millimeter) then no constraint on the function A (courtesy gef@iap.fr) 2- The mass of the field is smaller than 10-3 eV (range larger than the millimeter) then

  17. Quintessence and the rest of the world Consequences: 1- Presence of a fifth force Ruled out! Example of the SUGRA model (no systematic exploration of the parameters space yet) 2- Violation of the (weak) equivalence principle (because they are two Higgs!) Current limits: To be improved by the CNES satellite “Microscope” 3- Other possible effects Variation of constants (fine structure constant etc …), proton to electron mass ratio, Chameleon model (hence, one can have )

  18. Quintessence and the rest of the world The quintessence potential is modified by the hidden sector The fermions mass pick up a quintessence dependence The potential is still of the runaway type and its mass is mQ» H0¿ 10-3 eV The potential acquires a minimum and the mass of Q typically becomes the gravitino mass m3/2À 10-3eV The model is safe from the gravity experiments point of view but is not interesting from the cosmological point of view One has to check whether the model is safe from the gravity experiments point of view.

  19. Conclusions Conclusions: 1- Coupling Dark energy to the observable fields predicts a bunch of different effects. In particular, violation of the EP is directly linked to the fact that they are two Higgs in the MSSM. 2- Probing dark energy is not only measuring the equation of state (cosmological test). MICROSCOPE (CNES) will measure the EP in 2008. 3- Detailed predictions require detailed models. Can be used to rule out models. More in hep-th/0605228, astro-ph/0606306 Punch-line: Either the model is fine from the gravity point of view because its mass is large (gravitino mass) but uninteresting from the cosmological point of view or it is fine from the cosmological point of view because its mass is small (Hubble length) but, then, the corresponding range of the force is large and it is difficult to build a model consistent from the gravity experiments point of view.

  20. Quintessence One postulates the presence of a scalar field Q with a runaway potential and  = 0 Two parameters: M and  If the field is subdominant, there exists a particular solution such that NB: is the equation of state of the background fluid, i.e. 1/3 or 0 The field tracks the background and eventually dominates

  21. Quintessence The particular solution is an attractor and is joined for a huge range of initial conditions radiation The attractor is joined matter quintessence The coincidence problem is solved: the acceleration starts recently The attractor is joined

  22. Quintessence The equation of state is a time-dependent (or redshift -dependent) quantity The present value is negative and different from -1. Hence it can be distinguished from a cosmological constant Of course, the present value of the equation of state is also independent from the initial conditions

  23. Quintessence When the field starts dominating the matter content of the Universe, it leaves the particular solution. This one can be written as This happens for The mass of the field (defined as the second derivative of the potential) is

  24. Quintessence The energy scale M of the potential is fixed by the requirement that the quintessence energy density today represents 70% of the critical energy density Electroweak scale The index  is a free quantity. However,  cannot be too large otherwise the equation of state would be too far from -1 even for the currently available data

  25. Quintessence The evolution of the small inhomogeneities is controlled by the perturbed Klein-Gordon equation Clustering of quintessence only on scales of the order of the Hubble radius

  26. Hidden sector parameterization Quintessence and the rest of the world Technically, the mixing originates from the following Total Kahler Total super-potential Breaking SUSY

  27. Quintessence and the rest of the world Let us first consider how the “dark” sector is modified Quintessence potential coming from the dark sector only This term is constant if the hidden sector is stabilized Application to the SUGRA potential Gravitino mass= mass of the quintessence field if the hidden sector is stabilized

  28. Quintessence and the rest of the world Application to the Higgs Mechanism Through the soft terms, the (F-terms) Higgs potential becomes Q-dependent. Additional dependence can show up through the gauge coupling functions (D-terms).

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