GSI-FAIR Colloquium

Extreme Light Infrastructure (ELI) Project and User Facility Implementation

by Georg Korn (ELI Prague)

Europe/Berlin
Main Lecture Hall (GSI)

Main Lecture Hall

GSI

Description

We will be giving an overview on the development of the ELI facilities and in particular the “ELI-beamline facility” being currently implemented and opened as user facilities within the Extreme Light Infrastructure (ELI) project based on the European ESFRI (European Strategy Forum on Research Infrastructures) process. ELI-Beamlines will be the high-energy, repetition-rate laser pillar of the ELI project. The main objective of the ELI-Beamlines facility is the delivery of ultra-intense high-energy pulses for high-field experiments and the generation and applications of high-brightness X-ray sources and accelerated particles. The high power laser systems currently prepared and used for the generation of higher repetition rate sources of x-rays and particles are L1 (Allegra), a 1 kHz diode pumped laser produced sub-20fs OPCPA system, and the L3 (HAPLS), a 10 Hz, 1 PW (30fs) laser using as the active medium Ti:sapphire with new gas cooled diode pumped Nd doped Glass pump laser. The L4 (10 PW, 1.5 kJ, 150fs, 1 shot /minute) laser is currently being installed at the ELI-Beamline facility. The lasers will be able to provide focused intensities attaining >10 18-21 Wcm-2 (L1, L3) suitable for generation of x-rays and particles (electrons and ions), whereas L4 should exceed 1023 Wcm-2 for high field experiments in the future. We will discuss the infrastructure concerning the availability of experimental areas for high-field physics, including secondary sources of particles and x-rays in the energy range between 20 eV - 100 keV and few MeV and their practical implementation at the ELI-Beamline user facility. The sources are either based on direct interaction of the laser beams with gaseous targets (high order harmonics) or will first accelerate electrons which then will interact with laser produced wigglers (Betatron radiation) or directly be injected into undulators (laser driven LUX or later X-FEL). The direct interaction (collision) of laser accelerated electrons with the intense focused laser beam again will lead to short pulse high energy radiation via Compton or Thomson scattering for different applications opening also the route to fundamental physics investigations in high intensity interaction due to the 4 gamma2 Lorentz boost of the intensity seen by high energy (gamma2 > 106) electrons.

Poster