Gravitational Waves from Phase Transition in a Supersymmetric Left-Right Model
Abstract
We investigate the cosmological phase transition dynamics in a supersymmetric left-right symmetric model based on the gauge group SU(3)C × SU(2)L × SU(2)R × U(1)B-L that addresses the strong CP problem through extended parity symmetry and doublet-doublet splitting. We compute the finite temperature effective potential including one-loop Coleman-Weinberg corrections, thermal contributions, and daisy resummation to determine whether the SU(2)R × U(1)B-L U(1)Y symmetry breaking transition can produce observable gravitational waves. For phenomenologically viable parameters satisfying current LHC constraints, we find that the phase transition is strongly first-order with nucleation temperature Tn 0.5 vR, transition strength parameter α 0.01-0.3, and inverse duration β/H 100. The resulting stochastic gravitational wave background peaks at frequencies f 0.1-1 Hz with amplitude h2GW 10-14-10-12. We find that there is a parameter region where the gravitational wave spectrum overlaps with DECIGO/BBO sensitivity curves, providing a potentially observable signature connecting the theoretical solution to the strong CP problem with gravitational wave experiments.
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