Natural Supercooling and Reheating along Supersymmetric Flat Directions and Observable Gravitational Waves at the Einstein Telescope and the Cosmic Explorer

Abstract

We study supercooled first-order phase transitions in a supersymmetric hidden sector with a spontaneously broken U(1)X, focusing on the frequency range of the Einstein Telescope and Cosmic Explorer. Along the D-flat direction the tree-level quartic vanishes, so the barrier is generated radiatively by soft SUSY-breaking splittings. In the DR scheme the gaugino mass Mλ sets the barrier depth, while the soft scalar mass m0 stabilizes the broken vacuum. For Mλ/vX0.05--0.23, the predicted signal reaches Ω GWh23×10-10 near the percolation boundary. The observable amplitude depends sensitively on the portal coupling δ through the hidden-to-visible temperature ratio at percolation: for a cold initial hidden sector the signal rises from the ET floor at δ=10-6 to Ω GWh27×10-11 as the sectors approach thermal contact at δ=10-4, while a hotter initial hidden sector gives a large signal already for weak portal coupling. We follow this evolution with an 11-variable Boltzmann system that separates the cold nucleating exterior from the reheated true-vacuum interior; reheating mainly enters through the energy budget and redshift factors. The same hidden sector can reproduce Ω CDMh2=0.12 through relativistic dark-quark freeze-out followed by entropy dilution from hidden-Higgs decay, with mq30--800\;keV and N eff few×10-5.