Electroweak baryogenesis is an interesting theoretical scenario, which demands physics beyond the Standard Model at energy scales of the order of the weak boson masses. It has been recently emphasized that, in the presence of light stops, the electroweak phase transition can be strongly first order, opening the window for electroweak baryogenesis in the MSSM. For the realization of this scenario, the Higgs boson must be light, at the reach of the LEP2 collider. In this article, we compute the baryon asymmetry assuming the presence of non-trivial CP violating phases in the parameters associated with the left-right stop mixing term and the Higgsino mass µ. We conclude that a phase | sin φ µ | > 0.01 and Higgsino and gaugino mass parameters |µ| ≃ M 2 , and of the order of the electroweak scale, are necessary in order to generate the observed baryon asymmetry.February 1997 *
Spherically symmetric static empty space solutions are studied in f (R) theories of gravity. We reduce the set of modified Einstein's equations to a single equation and show how one can construct exact solutions in different f (R) models. In particular, we show that for a large class models, including e.g. the f (R) = R − µ 4 /R model, the Schwarzschild-de Sitter metric is an exact solution of the field equations. The significance of these solutions is discussed in light of solar system constraints on f (R) theories of gravity.
Modified theories of gravity have recently been studied by several authors as possibly viable alternatives to the cosmological concordance model. Such theories attempt to explain the accelerating expansion of the universe by changing the theory of gravity, instead of introducing dark energy. In particular, a class of models based on higher order curvature invariants, so-called f (R) gravity models, has drawn attention. In this letter we show that within this framework, the expansion history of the universe does not uniquely determine the form of the gravitational action and it can be radically different from the standard Einstein-Hilbert action. We demonstrate that for any barotropic fluid, there always exists a class of f (R) models that will have exactly the same expansion history as that arising from the Einstein-Hilbert action. We explicitly show how one can extend the Einstein-Hilbert action by constructing a f (R) theory that is equivalent on the classical level. Due to the classical equivalence between f (R) theories and Einstein-Hilbert gravity with an extra scalar field, one can also hence construct equivalent scalar-tensor theories with standard expansion.
Static spherically symmetric perfect fluid solutions are studied in metric f (R) theories of gravity. We show that pressure and density do not uniquely determine f (R) ie. given a matter distribution and an equation state, one cannot determine the functional form of f (R). However, we also show that matching the outside Schwarzschild-de Sitter-metric to the metric inside the mass distribution leads to additional constraints that severely limit the allowed fluid configurations.
Stable non-topological solitons, Q-balls, are studied using analytical and
numerical methods. Three different physically interesting potentials that
support Q-ball solutions are considered: two typical polynomial potentials and
a logarithmic potential inspired by supersymmetry. It is shown that Q-balls in
these potentials exhibit different properties in the thick-wall limit where the
charge of a Q-ball is typically considerably smaller than in the thin-wall
limit. Analytical criteria are derived to check whether stable Q-balls exists
in the thick-wall limit for typical potentials. Q-ball charge, energy and
profiles are presented for each potential studied. Evaporation rates are
calculated in the perfect thin-wall limit and for realistic Q-ball profiles. It
is shown that in each case the evaporation rate increases with decreasing
charge.Comment: 25 page
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