ELI Beamlines’ latest advancement is its High-repetition-rate Advanced Petawatt Laser System (HAPLS). HAPLS is the first diode-pumped and highest average power petawatt system (300 W, 10 Hz repetition rate) ever built. HAPLS can achieve focused intensities between 1021-1023 watts per square centimeter, the equivalent of all sunlight as it arrives at the earth being focused to the diameter of a human hair. Achieving the extreme high-power, short-pulse features of HAPLS required rigorous design validation and highly nuanced beam propagation capabilities.
The success of ELI Beamlines’ projects generates ongoing high-funding stability for both the organization and related organizations. This, combined with the precision and unprecedented capabilities its technologies afford to other scientists, make it crucial for ELI Beamlines to build systems efficiently and practically. This ensures collaborators can work together effectively and their discoveries are brought to the rest of the community in timely and impactful ways.Using OpticStudio, the team modeled phase-to-amplitude modulations during beam propagation to experimental chambers, where the beam is focused up to 100 meters of propagation with off-axis parabolas. OpticStudio was then used to assess intensity modulations, as well as to predict acceptable phase errors as the new HAPLS system was commissioned.
- OpticStudio enabled sub-system and beam transport system designs for HAPLS, the world’s first diode-pumped and highest-repetition-rate petawatt laser system.
- The beam transport model accurately predicted that phase-to-amplitude modulations during free space beam propagation would not lead to intensity spikes that exceeded the laser-induced damage threshold (LIDT) on high-power, dielectrically coated mirrors.
- Project design goals were achieved in far less time using the Zemax software than it would have taken to produce a likely lower-quality result using in-house code development efforts.
- Using OpticStudio saved millions of euros and two to three years of development time due to reduced engineering and coding complexity achieved through beam transport operation predictions.
