Physics – High Energy Physics – High Energy Physics - Phenomenology
Scientific paper
2009-07-29
Physics
High Energy Physics
High Energy Physics - Phenomenology
10 pages, 1 figure
Scientific paper
By using a No-Scale Supergravity model, which was proved to explain WMAP observations appropriately, a mechanism of supersymmetry breaking and a preheating just after the end of inflation are investigated. Non-thermal production rate of gravitino is estimated as well as supersymmetry breaking mechanism numerically. The supersymmetry breaking is triggered by the inflaton superfield alone and the interchange of supersymmetry breaking fields does not occur in our model. By the instant preheating mechanism, the preheating temperature is calculated through the process where the inflaton decays into right handed sneutrinos, which will decay into Higgs fields and others. The obtained value of the yield variable for gravitino is rather large, however, the primordial gravitinos decay very rapidly and the preheating temperature is lower than the gravitino mass, the effect to the standard Big Bang Nucleosynthesis (BBN) scenario is negligible. Though a tachyonic state seems to appear from modular field T, it will be solved by assuming the spontaneous breaking of modular invariance. Whether or not the fact is a defect, we emphasize that the model still seems phenomenologically effective.
Fukuoka Toyokazu
Hayashi Mitsuo J.
Kasari Hikoya
Koshimizu Yuta
Sakai Takao
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