27 January 2020 Congratulations to New ICFO PhD graduate

Dr Daniel Sánchez Peacham


Thesis Committee

Dr. Daniel Sánchez graduated with a thesis entitled “Development of a High Intensity Mid-Ir OPCPA Pumped by a HO:YLF Amplifier” Dr. Daniel Sánchez received his Master degree in Photonics from the joint program between the UPC, UAB, UB and ICFO before joining the Attoscience and Ultrafast Optics research group led by ICREA Prof. at ICFO Dr. Jens Biegert. During his PhD studies, Daniel studied new generations of laser systems for the study of strong-field phenomena. Dr. Sánchez’s’s thesis, entitled “Development of a High Intensity Mid-Ir OPCPA Pumped by a HO:YLF Amplifie”, was supervised by Prof. Dr. Jens Biegert.

ABSTRACT:
The continuous development of laser sources delivering ultra-short light pulses underpins much of the current progress in experimental science, particularly in the domain of physics concerned with strong-field phenomena. Laser systems that allow scaling of strong-field experiments to unexplored regions of the electromagnetic spectrum, specially the mid-IR range (2 µm < ¿ < 20 µm), have proved to be a powerful tool enabling the study of new physical processes. It is becoming clear however, that conventional laser sources are unsuited for this purpose, and in order to fully investigate these novel regimes a new generation of laser systems is required.

This thesis describes a new laser source of high-intensity, mid-IR light. A long-wavelength pumped optical parametric chirped pulse amplifier (OPCPA) design is chosen as the architecture for this laser, overcoming many of the drawbacks hindering other approaches. This thesis presents two novel sub-systems required for the successful development of a mid-IR OPCPA. The first is a compact, fibre-driven source of broadband mid-IR pulses relying on difference frequency generation (DFG) in the nonlinear crystal CdSiP2. This laser is the seed source in the OPCPA and supports transform-limited pulses corresponding to less than 3 optical cycles at the operating wavelength of 7 µm. The second sub-system is a pump source based on a Ho:YLF chirped pulse amplifier (CPA) pumped by commercial Tm-fibre laser. The pump system delivers over 0.25 J of pulse energy at a wavelength of 2052 nm.

The laser system described in this thesis is a developmental milestone towards the realisation of a multi-mJ source of few-cycle duration, carrier-to-envelope phase (CEP) stable mid-IR pulses. The system is designed to operate at a centre wavelength of 7 µm, delivering pulses with an energy of 0.2 mJ and a temporal duration of 180 fs at 100 Hz repetition rate. The output parameters of the laser presented in this work lead to a peak power of 1.1 GW and potentially a peak intensity of 7·1014 W/cm2. These values are already compatible with strong-field experiments and enable a ponderomotive force 77 times larger than a standard Ti:Sapphire laser.


THESIS COMMITTEE:
Dr. Valentin Petrov, Max Born Institute for Nonlinear Optics and Short Pulse Spectroscopy

Prof David Artigas - ICFO/UPC

Dr Olivier Chalus, Thales LAS France

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