Superradiant emission stimulated by vortex-antivortex pair production in layered superconductors

Abstract

We report numerical simulations of coupled sine-Gordon and heat diffusion equations describing dynamic states stimulated by a trapped vortex driven by dc current in a stack of up to N=321 Josephson junctions. It is shown that the Cherenkov wake behind the vortex shuttle trapped in the stack can trigger proliferation of counter-propagating vortices and antivortices which get synchronized and form large-amplitude standing electromagnetic waves. This happens if the dc current density J exceeds a threshold value Js which can be well below the Josephson interlayer critical current density Jc for underdamped junctions. The cavity modes stimulated by the vortex-antivortex pair production cause peaks in the radiated power PN(J) with a nearly monochromatic spectrum at discrete values of J corresponding to the zero-field Fiske resonances. The power PN(J) was evaluated for small rectangular stacks in the magneto-dipole approximation and for large stacks in a single mode state. For small stacks, the highest peak in PN(J) increases rapidly, PN N6, with the number of junctions at N≤ 81 and gradually slows down to PN N2 at 161≤ N≤ 321. For stacks larger than the radiated wavelength, we obtained PN N5 at N 200-300 and PN N2 at larger N. For stacks with up to 321 junctions and representative parameters of Bi2Sr2CaCu2O8+δ, we observed moderate overheating and no hotspots. The vortex-antivortex pair production can amplify THz radiation from Bi2Sr2CaCu2O8+δ mesas for which trapping Josephson vortices could be used to stimulate THz emission at subcritical currents and optimize the radiation output.