Add to ORKGWe study the quark-hadron transition in the early Universe and compute the amplitude of isothermal baryon-number fluctuations that emerge from this transition along with their effects on primordial nucleosynthesis. We find that such fluctuations are a natural consequence of a first-order phase transition occurring in the strongly interacting system. Fluctuation-generating mechanisms are discussed. We estimate the nucleation rate and derive the mean separation between fluctuations. It is shown that the amplitude of the fluctuations depends sensitively on the phase coexistence temperature Tc and on the baryon transmission probability h at the phase boundary. For realistic values of h and Tc the fluctuations are large and have a significant ef...
Baryon inhomogeneities are generated early in the universe. These inhomogeneities affect the phase t...
We study big bang nucleosynthesis in the presence of large mass scale, nonlinear entropy fluctuation...
In the standard hot big bang theory, when the Universe was about 1-10μs old, the cosmological matter...
We study the quark-hadron transition in the early Universe and compute the amplitude of isothermal b...
We present a simple thermodynamic model of the quark-hadron transition in the early universe and use...
We study the quark-hadron phase transition in the early Universe and the effect of baryon density in...
A first-order phase transition is likely to have occurred in the early universe at the end of the qu...
Borghini N, Cottingham WN, Mau RV. Possible cosmological implications of the quark-hadron phase tran...
A QCD phase transition in the early universe could have left inhomogeneities in the baryon to photon...
In the early Universe, strongly interacting matter was a quark–gluon plasma. Both lattice computatio...
We report on calculations of primordial nucleosynthesis in baryon-number inhomogeneous big bang mode...
We examine effects on primordial nucleosynthesis from a truly random spatial distribution in the bar...
We study the quark deconfinement phase transition in hot beta-stable hadronic matter. Assuming a fir...
We study the dynamics of the quark-hadron transition for a scenario in which the Universe is matter ...
Primordial baryon-number fluctuations can be damped at temperatures 20 keV when the photon mean free...
Baryon inhomogeneities are generated early in the universe. These inhomogeneities affect the phase t...
We study big bang nucleosynthesis in the presence of large mass scale, nonlinear entropy fluctuation...
In the standard hot big bang theory, when the Universe was about 1-10μs old, the cosmological matter...
We study the quark-hadron transition in the early Universe and compute the amplitude of isothermal b...
We present a simple thermodynamic model of the quark-hadron transition in the early universe and use...
We study the quark-hadron phase transition in the early Universe and the effect of baryon density in...
A first-order phase transition is likely to have occurred in the early universe at the end of the qu...
Borghini N, Cottingham WN, Mau RV. Possible cosmological implications of the quark-hadron phase tran...
A QCD phase transition in the early universe could have left inhomogeneities in the baryon to photon...
In the early Universe, strongly interacting matter was a quark–gluon plasma. Both lattice computatio...
We report on calculations of primordial nucleosynthesis in baryon-number inhomogeneous big bang mode...
We examine effects on primordial nucleosynthesis from a truly random spatial distribution in the bar...
We study the quark deconfinement phase transition in hot beta-stable hadronic matter. Assuming a fir...
We study the dynamics of the quark-hadron transition for a scenario in which the Universe is matter ...
Primordial baryon-number fluctuations can be damped at temperatures 20 keV when the photon mean free...
Baryon inhomogeneities are generated early in the universe. These inhomogeneities affect the phase t...
We study big bang nucleosynthesis in the presence of large mass scale, nonlinear entropy fluctuation...
In the standard hot big bang theory, when the Universe was about 1-10μs old, the cosmological matter...