Darker and brighter branes: Suppression and enhancement of photon production in a strongly coupled magnetized plasma

We extend our holographic analysis of the emission of photons by a strongly coupled plasma subject to a very intense external magnetic field. We previously showed that in a particular model, any photon produced by the plasma had to be in its only polarization state parallel to the reaction plane. In this paper we consider a construction that relaxes a formerly imposed constraint, permitting the emission of photons with either out-plane or in-plane polarization. This constitutes a completion of our former study because the fully back-reacted equations decouple for these two polarization states in such a manner that those involving the in -plane are identical to the ones we explored previously. In view of the above, part of the details concerning the calculations and of the numerical results for the differential rate of emitted photons that we present here correspond exactly to those omitted in our preceding letter. One of our main results is that the production of photons is increased by the introduction of a nonvanishing magnetic field with an intensity up to a value B-theta, above which the effect is reversed and said production becomes lower than the B = 0 case. The characteristic intensity B-theta depends on the propagation direction and tends to zero as the photon momentum becomes aligned with the magnetic field. Additionally, we also show that the magnetic field has the effect of increasing the value of the elliptic flow, providing a possible explanation for the excess measured in collision experiments. The holographic model is constructed using an effective five-dimensional action that includes a scalar field in addition to the constant magnetic field.

Automated summary

We expand our holographic analysis to study the emission of photons in a strongly coupled plasma under a very intense external magnetic field. By relaxing certain constraints, we demonstrate that photons can have either out-plane or in-plane polarization. Our calculations and numerical results complement our previous findings, showing that the introduction of a nonvanishing magnetic field can increase photon production up to a certain intensity, beyond which the effect is reversed. This magnetic field also increases the elliptic flow, providing a possible explanation for excess measured in collision experiments.