Project Member: 1.2 "Ultrafast Laser Physics and Nonlinear Optics"
Mid-infrared laser becoming increasingly important for high-harmonic generation (attosecond pulse), development of novel x-ray sources, and strong-field physics. Optical parametric chirped-pulse amplification (OPCPA) seems to be the most promosing approach to generate high power midinfrared pulses, i.e. few-cyle pulses with pulse energies in the mJ range at kHz repetition rates. However, powerful pump lasers are required.
To exploite the relatively high nonlinear coefficient of non-oxide crystals, such as ZnGeP2, the emitted wavelength of the pump sources have to be above 2 µm. This ensures that the absorption in the nonlinear crystals is significantly reduced. Here we concentrate our research on regenerative amplifiers using Ho:YLF as a gain medium with a central wavelenght of around 2050 nm. Pulse energies in the millijoule regime (~10 mJ) have been achieved directly from our regenerative amplifier which was conceptually designed as a ring cavity. With the entire setup shown in Fig. 1 we are able to generate pulse energies of up to 55 mJ at 1 kHz with very low pulse-to-pulse fluctuations (rms < 0.5 %).
Fig. 1. High power 2 µm laser delivering pulse energies of up to 55 mJ. The seed-source is a three-stage system consiting of a fs Er:fiber laser, a super-continuum highly nonlinear fiber and a Tm:fiber pre amplifier. After 24 round trips a state of operation is reached where the regenerative amplifier emits stable pulses (rms < 0.3 %) of around 10 mJ at 1 kHz. A booster (two Ho:YLF crystals) stage raises the pulse energy to > 50 mJ.
2013-present Postdoc at the Max Born Institute: High-power mid-infrared lasers
2013 Dissertation “Programmable ultrashort pulsed highly localized wave packets” at the Max Born Institute
2008-2013 Ph. D. student at the Max Born Institute
2008 Master thesis “Spatio-spectral shaping of few-cycle laser pulses with liquid crystal displays” at the Max Born Institute
2006-2008 Study of -Photonics- at the University of Applied Science Wildau (Graduation: Master of Engineering)
2005 Diploma thesis “Spatio-spectrally resolved characterization of ultrashort laser pulses” at the Max Born Institute (MBI) for Nonlinear Optics and Short Pulse Spectroscopy
2001-2005 Study of -Physical Engineering- of the department Engineering / Industrial Engineering with Business Studies at the University of Applied Science Wildau (Graduation: Diploma-Engineer)
- Spatio-temporal coherence mapping of few-cycle vortex pulses Scientific Reports 4 (2014) 7148/1-7
- Refractive-diffractive dispersion compensation for optical vortex beams with ultrashort pulse durations Applied Optics 53 (2014) 7304-7211
- Spatio-temporal localization of ultrashort-pulsed Bessel beams at extremely low light level Non-Diffracting Waves J. Wiley (2013) 257-270
- Adaptive generation and diagnostics of linear few-cycle light bullets Applied Sciences 3 (2013) 139-152
- Nanostructured fibers for sub-10 fs optical pulse delivery Laser & Photonics Reviews 7 (2013) 566–570
- First measurement of the non-instantaneous response time of a χ(3) nonlinear optical effect Ultrafast Phenomena XVIII EDP Sciences (2013) 12005/1-3
- Verbesserte Diagnostik ultrakurzer Laserpulse - Kombinierte Messung von Wellenfront und ortsaufgelöster Pulsdauer Laser & Photonik 1 (2013) 32-35
- Temporal self-reconstruction of few-cycle nondiffracting wavepackets SPIE Proceedings Series 8611 (2013) 86110S
- MEMS axicons for nondiffracting line shaping of ultrashort pulses SPIE Proceedings Series 8637 (2013) 86370M/1-9
- Adaptive shaping of nondiffracting wavepackets for applications in ultrashort pulse diagnostics Non-Diffracting Waves J. Wiley (2013) 271-285