Efficient Electron Acceleration and MeV Photon Radiation in Relativistically Transparent Magnetic Filaments

In relativistically transparent interactions, lasers with intensity above 10²⁰ W/cm² drive relativistic current filaments with ultrastrong azimuthal magnetic fields in classically overdense plasmas. These magnetic fields trap electrons, which are directly accelerated by the laser pulse to hundreds of MeV and efficiently radiate MeV-scale photons by synchrotron radiation. We present scaling laws that describe the radiated photon energy and radiation efficiency of this process, and the results of initial experiments to test this phenomenon at the Texas Petawatt Laser (TPW). The analytical scaling laws are validated by 3-D particle-in-cell simulations in two regimes of focal radius. Radiation efficiency is predicted to exceed 10% for laser intensity above 6×10²¹ W/cm². Experiments at TPW using moderate laser intensity (10²¹ W/cm²) demonstrate the predicted signatures of electron acceleration and x-ray radiation from a subset of microchannel targets filled with low-density CH foam. Optimization of this ultrafast photon source for applications in high-energy-density, nuclear, and high-field physics is discussed.