Read more
This thesis presents first successful experiments to carrier-envelope-phase stabilize a high-power mode-locked thin-disk oscillator and to compress the pulses emitted from this laser to durations of only a few-optical cycles. Moreover, the monograph introduces several methods to achieve power-scalability of compression and stabilization techniques. All experimental approaches are compared in detail and may serve as a guideline for developing high-power waveform controlled, few-cycle light sources which offer tremendous potential to exploit extreme nonlinear optical effects at unprecedentedly high repetition rates and to establish table-top infrared light sources with a unique combination of brilliance and bandwidth. As an example, the realization of a multi-Watt, multi-octave spanning, mid-infrared femtosecond source is described. The thesis starts with a basic introduction to the field of ultrafast laser oscillators. It subsequently presents additional details of previously published research results and establishes a connection between them. It therefore addresses both newcomers to, and experts in the field of high-power ultrafast laser development.
List of contents
Introduction.- Proof of Concept: Few-Cycle Pulse Generation and Carrier-Envelope-Phase Stabilization.- Power Scalable Concepts.- From the Near- to the Mid-Infrared.- Outlook and Conclusions.- Appendix.
About the author
Marcus Seidel was born in Marienberg, Germany, in 1986. He studied physics at the Free University of Berlin, Germany, and the University of Rostock, Germany, from where he received his Diploma in Physics in 2012. Additionally, he obtained an M.Sc. degree in optics and photonics from the University of Central Florida in 2011. From 2012 to 2017, he conducted his PhD work at the Max-Planck Institute of Quantum Optics (MPQ) in Garching, Germany. Since mid-2017, he has been working as a postdoc in the Nanostructures Laboratory at the Institut de Science et d'Ingénierie Supramoléculaires (I.S.I.S.) in Strasbourg, France.
Summary
This thesis presents first successful experiments to carrier-envelope-phase stabilize a high-power mode-locked thin-disk oscillator and to compress the pulses emitted from this laser to durations of only a few-optical cycles. Moreover, the monograph introduces several methods to achieve power-scalability of compression and stabilization techniques. All experimental approaches are compared in detail and may serve as a guideline for developing high-power waveform controlled, few-cycle light sources which offer tremendous potential to exploit extreme nonlinear optical effects at unprecedentedly high repetition rates and to establish table-top infrared light sources with a unique combination of brilliance and bandwidth. As an example, the realization of a multi-Watt, multi-octave spanning, mid-infrared femtosecond source is described. The thesis starts with a basic introduction to the field of ultrafast laser oscillators. It subsequently presents additional details of previously published research results and establishes a connection between them. It therefore addresses both newcomers to, and experts in the field of high-power ultrafast laser development.
