1. Towards Schwinger production of magnetic monopoles in heavy-ion collisions
- Author
-
David L.-J. Ho, Oliver Gould, Arttu Rajantie, and Helsinki Institute of Physics
- Subjects
High Energy Physics - Theory ,Electromagnetic field ,Instanton ,PAIR PRODUCTION ,High Energy Physics::Lattice ,Magnetic monopole ,FOS: Physical sciences ,Astronomy & Astrophysics ,BARYON NUMBER VIOLATION ,114 Physical sciences ,01 natural sciences ,Physics, Particles & Fields ,High Energy Physics - Phenomenology (hep-ph) ,SEARCH ,QUANTUM-FIELD THEORY ,0103 physical sciences ,SCATTERING ,FALSE VACUUM ,010306 general physics ,Nuclear Experiment ,Physics ,Science & Technology ,Spacetime ,010308 nuclear & particles physics ,hep-th ,Space time ,THERMAL PRODUCTION ,IN-FIELD ,hep-ph ,HOMOGENEOUS ELECTRIC-FIELD ,Magnetic field ,High Energy Physics - Phenomenology ,Pair production ,High Energy Physics - Theory (hep-th) ,Quantum electrodynamics ,Physical Sciences ,Perturbation theory (quantum mechanics) ,CHARGE - Abstract
Magnetic monopoles may be produced by the Schwinger effect in the strong magnetic fields of peripheral heavy-ion collisions. We review the form of the electromagnetic fields in such collisions and calculate from first principles the cross section for monopole pair production. Using the worldline instanton method, we work to all orders in the magnetic charge, and hence are not hampered by the breakdown of perturbation theory. Our result depends on the spacetime inhomogeneity through a single dimensionless parameter, the Keldysh parameter, which is independent of collision energy for a given monopole mass. For realistic heavy-ion collisions, the computational cost of the calculation becomes prohibitive and the finite size of the monopoles needs to be taken into account, and therefore our current results are not applicable to them-we indicate methods of overcoming these limitations, to be addressed in further work. Nonetheless, our results show that the spacetime dependence enhances the production cross section and would therefore lead to stronger monopole mass bounds than in the constant-field case.
- Published
- 2019