| Popis: |
Attosecond pulses of coherent extreme ultraviolet (XUV) light are instrumental for studying sub-atomic dynamics, and are often produced from a free electron laser (FEL) by electron microbunches in an undulator. An optical-FEL (OFEL) utilizes a counter-propagating laser pulse instead of an undulator, and has been proposed as a more compact and tunable source than a FEL. Yet, an OFEL is difficult to realize because of the high electron density required and subsequent high emittance. We demonstrate that broadband coherent XUV light, which in the temporal domain corresponds to a train of attosecond pulses with 8-as duration at 92-as intervals, can be generated by microbunching of relativistic electrons and positrons in an optical laser pulse. The symmetry between electrons and positrons in the bunch stabilizes the system and enables the rapid formation of dense microbunches over a ten-micrometer distance instead of the tens of meters typically required in an undulator. The high microbunch density and the stable spectral phase up to emitted photon energies of about 350 eV, allow for the creation of orders of magnitude more compact sources of XUV light that could be employed in physics, chemistry, biology, and industry. |
