Squeezing Cosmological Phase Transitions with International Pulsar Timing Array
Abstract
A first-order MeV-scale cosmological phase transition (PT) can generate a peak in the power spectrum of stochastic gravitational wave background around nanohertz frequencies. With the recent International Pulsar Timing Array data release two covering nanohertz frequencies, we search for such a phase transition signal. For the standard 4-parameter PT model, we obtain the PT temperature [66 MeV, 30 GeV], which indicates that dark or QCD phase transitions occurring below 66 MeV have been ruled out at confidence level. This constraint is much tighter than [1 MeV, 100 GeV] from NANOGrav. We also give much tighter bounds on the PT duration , strength and friction than NANOGrav. For the first time, we find a positive correlation between and implying that PT temperature increases with increasing bubble nucleation rate. To avoid large theoretical uncertainties in calculating PT spectrum, we make bubble spectral shape parameters , , and four PT parameters free together, and confront this model with data. We find that pulsar timing is very sensitive to the parameter , and give the first clear constraint at confidence level.
Cite
@article{arxiv.2201.09295,
title = {Squeezing Cosmological Phase Transitions with International Pulsar Timing Array},
author = {Deng Wang},
journal= {arXiv preprint arXiv:2201.09295},
year = {2022}
}
Comments
5.5 pages, 4 figures