Paper detail

Plasma wakefields driven by intense, broadband, incoherent electromagnetic radiation

Non-linear wave-driven processes in plasmas are normally described by either a monochromatic pump wave that couples to other monochromatic waves, or as a random phase wave coupling to other random phase waves. An alternative approach involves an incoherent, random or broadband pump coupling to monochromatic and/or coherent structures in the plasma. This approach can be implemented through the wave kinetic model. In this model, the incoming pump wave is described by either a bunch (for coherent waves) or a sea (for random phase waves) of quasi-particles. A particle-in-cell type code has been developed to perform numerical simulations of such interactions using the quasi-particle approach. This code allows for a comparatively easy description of both random phase and coherent pump pulses coupling to slow electrostatic plasma waves, while providing an extended range of powerful diagnostics leading to a deeper physical insight into the dynamics of the fast waves. As an example, the propagation of short, intense laser pulses through a plasma has been simulated. A sample of the phenomena that can be studied for this case includes modulational instabilities, photon wave breaking and turbulence, and pulse compression, stretching, and chirping. The extensibility of the numerical implementation to other types of fast wave-slow wave interactions is also discussed.