Abstract
We study the evolution of the matter-antimatter asymmetry ({\eta}), the vorticity, and the hypermagnetic field in the symmetric phase of the early Universe, and in the temperature range 100 GeV < T < 10 TeV. We assume a configuration for the hypermagnetic field which includes both helical and non-helical (Bz) components. Consequently, the hypermagnetic field and the fluid vorticity can directly affect each other, the manifestations of which we explore in three scenarios. In the first scenario, we show that in the presence of a small vorticity and a large {\eta}eR, helicity can be generated and amplified for an initially strong Bz. The generation of the helical seed is due to the chiral vortical effect (CVE) and/or the advection term, while its growth is mainly due to the chiral magnetic effect (CME) which leads to the production of the baryon asymmetry, as well. The vorticity saturates to a nonzero value which depends on Bz, even in the presence of the viscosity, due to the back-reaction of Bz on the plasma. Increasing the initial vorticity, makes the values of the helicity, {\eta}s, and vorticity reach their saturation curves sooner, but does not change their final values at the onset of the electroweak phase transition. The second scenario is similar to the first except we assume that all initial {\eta}s are zero. We find that much higher initial vorticity is required for the generation process. In the third scenario, we show that in the presence of only a strong hypermagnetic field, {\eta}s and vorticity can be generated and amplified. Increasing the initial helicity, increases the final {\eta}s and vorticity. We find that although the presence of a nonzero initial Bz is necessary in all three scenarios, its increase only increases the final values of vorticity.
Highlights
Observations indicate that the Universe is magnetized on all scales
We study the evolution of the matter-antimatter asymmetry ðηÞ, the vorticity, and the hypermagnetic field in the symmetric phase of the early Universe, and in the temperature range 100 GeV ≤ T ≤ 10 TeV
After obtaining the evolution equations for the hypermagnetic and the velocity fields, we focus on the evolution of the hypercharge chiral magnetic coefficient cB and the chiral vortical coefficient cv that depend on the matter-antimatter asymmetries
Summary
Observations indicate that the Universe is magnetized on all scales. Magnetic fields exist everywhere in the Universe, from the stars to the galaxies and the intergalactic medium [1,2,3,4]. [37] investigated the production of the matter-antimatter asymmetry in the presence of the primordial hypermagnetic fields They considered the Abelian anomalous effects and generalized the ordinary magnetohydrodynamic equations to the anomalous magnetohydrodynamics (AMHD). In our previous work [50], we investigated the generation and growth of the hypermagnetic field in a chiral vortical plasma, taking into account the CVE and the CME in the symmetric phase of the early Universe, and in the temperature range 100 GeV ≤ T ≤ 10 TeV. The main purpose of this paper is to answer two important questions: First we investigate the possibility to generate and grow matter-antimatter asymmetries along with helical components of hypermagnetic field resulting in a net helicity, starting with a nonzero Bz and a small vorticity, with or without an initial right-handed electron asymmetry ηeR.
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