Add to ORKGWe present ongoing investigations of the first-order confinement transition of a composite dark matter model, to predict the resulting spectrum of gravitational waves. To avoid long autocorrelations at the first-order transition, we employ the Logarithmic Linear Relaxation (LLR) density of states algorithm. After testing our calculations by reproducing existing results for compact U(1) lattice gauge theory, we focus on the pure-gauge SU(4) theory related to the Stealth Dark Matter model
We discuss the stochastic gravitational-wave spectrum from dark confinement and chiral phase transit...
When studied at finite temperature, Yang-Mills theories in $3+1$ dimensions display the presence of ...
The density of states is calculated for a SU(2) and a compact U(1) lattice gauge theory using a modi...
We present ongoing investigations of the first-order confinement transition of a composite dark matt...
Many models of composite dark matter feature a first-order confinement transition in the early Unive...
Many models of composite dark matter feature a first-order confinement transition in the early Unive...
Many models of composite dark matter feature a first-order confinement transition in the early Unive...
Extensions of the standard model that lead to first-order phase transitions in the early universe ca...
Extensions of the standard model that lead to first-order phase transitions in the early universe ca...
I present first results from ongoing lattice investigations into the finite-temperature dynamics of ...
First-order phase transitions in the early universe might produce a detectable background of gravita...
Extensions of the standard model that lead to first-order phase transitions in the early universe ca...
Extensions of the standard model that lead to first-order phase transitions in the early universe ca...
We use non-perturbative lattice calculations to investigate the finite-temperature confinement trans...
We pave the way for future gravitational-wave detection experiments, such as the Big Bang Observer a...
We discuss the stochastic gravitational-wave spectrum from dark confinement and chiral phase transit...
When studied at finite temperature, Yang-Mills theories in $3+1$ dimensions display the presence of ...
The density of states is calculated for a SU(2) and a compact U(1) lattice gauge theory using a modi...
We present ongoing investigations of the first-order confinement transition of a composite dark matt...
Many models of composite dark matter feature a first-order confinement transition in the early Unive...
Many models of composite dark matter feature a first-order confinement transition in the early Unive...
Many models of composite dark matter feature a first-order confinement transition in the early Unive...
Extensions of the standard model that lead to first-order phase transitions in the early universe ca...
Extensions of the standard model that lead to first-order phase transitions in the early universe ca...
I present first results from ongoing lattice investigations into the finite-temperature dynamics of ...
First-order phase transitions in the early universe might produce a detectable background of gravita...
Extensions of the standard model that lead to first-order phase transitions in the early universe ca...
Extensions of the standard model that lead to first-order phase transitions in the early universe ca...
We use non-perturbative lattice calculations to investigate the finite-temperature confinement trans...
We pave the way for future gravitational-wave detection experiments, such as the Big Bang Observer a...
We discuss the stochastic gravitational-wave spectrum from dark confinement and chiral phase transit...
When studied at finite temperature, Yang-Mills theories in $3+1$ dimensions display the presence of ...
The density of states is calculated for a SU(2) and a compact U(1) lattice gauge theory using a modi...