Abstract
We study the holographic Schwinger effect with magnetic field at RHIC and LHC energies by using the AdS/CFT correspondence. We consider both weak and strong magnetic field cases with Bll T^2 and Bgg T^2 solutions respectively. Firstly, we calculate separating length of the particle pairs at finite magnetic field. It is found that for both weak and strong magnetic field solutions the maximum value of separating length decreases with the increase of magnetic field , which can be inferred that the virtual electron-positron pairs become real particles more easily. We also find that the magnetic field reduces the potential barrier and the critical field for the weak magnetic field solution, thus favors the Schwinger effect. With strong magnetic field solution, the magnetic field enhances the Schwinger effect when the pairs are in perpendicular to the magnetic field although the magnetic field increases the critical electric field.
Highlights
The virtual electron-positron pairs can be materialized under the strong electric-field in quantum electrodynamic (QED)
Thence, we study the holographic Schwinger effect in the 5-dimensional Einstein–Maxwell system with a proper magnetic field range [49] produced in the non-central heavyion collisions at RHIC and LHC energies
We study the potential analysis with the test particle pairs separated in the x1-direction first, which means the particle pairs are transverse to the magnetic field
Summary
The virtual electron-positron pairs can be materialized under the strong electric-field in quantum electrodynamic (QED). Thence, we study the holographic Schwinger effect in the 5-dimensional Einstein–Maxwell system with a proper magnetic field range [49] produced in the non-central heavyion collisions at RHIC and LHC energies. This may give us some inspiration for studying the Schwinger effect through the experimental results. The production rate of Schwinger effect with the presence of electric and magnetic fields was discussed in [25]. With the magnetized background in this paper , we study the holographic Schwinger effect with a magnetic field by using the AdS/CFT correspondence.
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