Laboratory evidence for proton energization by collisionless shock surfing.

The origin of the high-energy particles flying through the Universe is still an open question. One identified source is collisionless shock waves formed when energy release from stars encounters the tenuous magnetized space environment. By interacting with the ambient, these shocks can transfer energy to particles, accelerating them. Characterization of these shocks has become very rich with satellite measurements at the Earth's bow shock and powerful numerical simulations, however identifying the exact mechanism, or combination of mechanisms enabling particle acceleration is still widely debated. Here we show that astrophysically relevant super-critical quasi-perpendicular magnetized collisionless shocks can be produced and characterized in the laboratory. Moreover, we observe a "foot" in the shock profile that is characteristic of super-critical shocks as well as the energization of protons picked up from the ambient gas to hundred keV. Our kinetic particle-in-cell simulations modeling of our laboratory event identified shock surfing as the proton acceleration mechanism. Our observations not only provide the first direct evidence of early stage ion energization by collisionless shocks, but they also highlight the role this particular mechanism plays in energizing ambient ions to feed further stages of acceleration. Furthermore, our results also open the door to future laboratory experiments investigating the possible transition to other mechanisms, when increasing the magnetic field strength, or the effect induced shock front ripples could have on acceleration processes.