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Stability of Q-balls and Catastrophe

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 Added by Nobuyuki Sakai
 Publication date 2008
  fields
and research's language is English




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We propose a practical method for analyzing stability of Q-balls for the whole parameter space, which includes the intermediate region between the thin-wall limit and thick-wall limit as well as Q-bubbles (Q-balls in false vacuum), using the catastrophe theory. We apply our method to the two concrete models, $V_3=m^2phi^2/2-muphi^3+lambdaphi^4$ and $V_4=m^2phi^2/2-lambdaphi^4+phi^6/M^2$. We find that $V_3$ and $V_4$ Models fall into {it fold catastrophe} and {it cusp catastrophe}, respectively, and their stability structures are quite different from each other.



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In this paper, we present a detailed study of the problem of classical stability of U(1) gauged Q-balls. In particular, we show that the standard methods that are suitable for establishing the classical stability criterion for ordinary (nongauged) one-field and two-field Q-balls are not effective in the case of U(1) gauged Q-balls, although all the technical steps of calculations can be performed in the same way as those for ordinary Q-balls. We also present the results of numerical simulations in models with different scalar field potentials, explicitly demonstrating that, in general, the regions of stability of U(1) gauged Q-balls are not defined in the same way as in the case of ordinary Q-balls. Consequently, the classical stability criterion for ordinary Q-balls cannot be applied to U(1) gauged Q-balls in the general case.
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