Formatvorlage des Untertitelmasters durch Klicken bearbeiten 1/26/15 1 kHz, multi-mJ Yb:KYW bulk regenerative amplifier 1 Ultrafast Optics and X-Ray Division,

Slides:

Advertisements

Similar presentations

Hi Repetition Rate MOPA Based Fibre Laser for Micro Machining Applications Bill O’Neill Centre of Industrial Photonics Institute for Manufacturing University.

Advertisements

R.6.2 Lasery Optoelektronika 2014 Dr hab. inż. B. B. Kosmowski 1.

Components of ultrafast laser system

Self-Guided Operation of Green-Pumped Singly Resonant

PHYS 252 Lasers1 Lasers What is stimulated emission? Well, there are two types of light emission that can occur with atoms! The kind that we have been.

Renata Bartula, Chris Hagen, Joachim Walewski, and Scott Sanders

High energy, high repetition rate pump laser system for OPCPAs A.-L. Calendron 1,2,3, L. E. Zapata 1,4, H. Çankaya 1,2, H. Lin 4 and F. X. Kärtner 1,2,3,4.

Characteristic evaluation of new laser crystals Rui Zhang ACCL Division V, RF-Gun Group Feb 20, 2015 SuperKEKB Injector Laser RF Gun Review.

Dye lasers The gain medium in a dye lasers is a solution made with an organic dye molecule. The solution is intensely coloured owing to the very strong.

Ultrafast Spectroscopy

PHOTONICS CENTER 6/3/20031External Cavity Laser Diode Arrays - Thermal Effects Gregory Blasche Bennett Goldberg Boston University Physics Department M.

Yb Fiber Laser System Xiangyu Zhou 19. Feb

SLAC XFEL Short Bunch Measurement and Timing Workshop 1 Current status of the FERMI project (slides provided by Rene Bakker) Photoinjector laser system.

Time-Bandwidth Products getting the average power of ultrafast DPSS lasers from hundreds of mW to tens of Watts by Dr. Thomas Ruchti CERN, April 2006 SESAM.

SAPPHiRE workshop, CERN 19 th Feb 2013 A SAPPHiRE Laser? Laura Corner Lasers for Accelerators group (L4A) John Adams Institute for Accelerator Science,

ILE OSAKA New Concept of DPSSL - Tuning laser parameters by controlling temperature - Junji Kawanaka ILE OSAKA US-Japan Workshop on Laser-IFE March.

The ILC Laser-wire system Sudhir Dixit The John Adams Institute University of Oxford.

High power ultrafast fiber amplifiers Yoann Zaouter, E. Cormier CELIA, UMR 5107 CNRS - Université de Bordeaux 1, France Stephane Gueguen, C. Hönninger,

S. Manz 1*, A. Casandruc 1, D. Zhang 1, J. Hirscht 1, S. Bayesteh 3, S. Keskin 1, J. Nicholls 4, T. Gehrke 3, F. Mayet 3, M. Hachmann 3, M. Felber 2, S.

DMP Product Portfolio Femtosecond Lasers Trestles Ti:Sapphire lasers …… fs; nm, mW Mavericks Cr:Forsterite lasers

NOISE IN OPTICAL SYSTEMS F. X. Kärtner High-Frequency and Quantum Electronics Laboratory University of Karlsruhe.

Palaiseau - FRANCE Spatio-Temporal Chirped Pulse Amplification for Avoiding Spectral Modifications in Ultra-Short Petawatt Lasers C. Radier1,2, F. Giambruno1,3,

A 5 fs high average power OPCPA laser system for attosecond pulse production Philip Bates, Yunxin Tang, Emma Springate and Ian Ross Central Laser Facility,

Opto CANADA 9-10 May 2002CAo6-515 Model calculation on the efficiency of PDT by pulsed laser application Hans-Georg Fercher, Dirk Meyer, and Hans-Jochen.

WHY ???? Ultrashort laser pulses. (Very) High field physics Highest peak power, requires highest concentration of energy E L I Create … shorter pulses.

GJ Van der Westhuizen, JP Burger, EG Rohwer, JN Maran Laser Research Institute, Department of Physics, University of Stellenbosch, South Africa NUMERICAL.

Yb:CaF 2 Diode-Pumped Regenerative Amplifier: Study and Optimization of Pulse Duration Versus Repetition Rate ICUIL, Watkins Glen, 26 th September-1 st.

Optics, Lasers, and Remote Sensing Department 1128 Microlasers and Nonlinear Optics R. Schmitt, D. Armstrong, A. Smith, B. Do, and Greg Hebner Sandia National.

Intra-cavity Pulse Shaping of Mode-locked Oscillators Shai Yefet, Naaman Amer and Avi Pe’er Department of physics and BINA Center of nano-technology, Bar-Ilan.

Efficient scaling of output pulse energy in static hollow fiber compressors X. Chen, A. Malvache, A. Ricci, A. Jullien, R. Lopez-Martens ICUIL 2010, Watkins.

Isao MATSUSHIMA, Hidehiko YASHIRO, Toshihisa TOMIE National Institute of Advanced Industrial Science and Technology (AIST) C , Umezono, Tsukuba,

Ultra-short pulse operation of all-optical fiber passively mode-locked

Folienvorlagen für Seminarvortrag. Novel laser concepts HR-mirror out coupling mirror disc cooling diode laser focusing optic diode laser focusing optic.

Compton based Polarized Positrons Source for ILC V. Yakimenko Brookhaven National Laboratory September 12, 2006 RuPAC 2006, Novosibirsk.

Lasers and RF-Timing Franz X. Kaertner

Injection Locked Oscillators Optoelectronic Applications E. Shumakher, J. Lasri, B. Sheinman, G. Eisenstein, D. Ritter Electrical Engineering Dept. TECHNION.

All-optical control of light on a silicon chip Vilson R. Almeida, Carlos A. Barrios, Roberto R. Panepucci & Michal Lipson School of Electrical and Computer.

Simple Multiwavelength Time-Division Multiplexed Light Source for Sensing Applications Thilo Kraetschmer and Scott Sanders Engine Research Center Department.

©LZH Livingston, La.; LIGO-G Status of 100 W Rod System at LZH Laserzentrum Hannover e. V. Hollerithallee 8 D Hannover Germany.

Optimized temperature/bandwidth operation of cryogenic Yb:YAG composite thin-disk laser amplifier 1 Ultrafast Optics and X-Ray Division, Center for Free-Electron.

Development of High-efficiency Yb:YAG Regenerative Amplifier for Industry Isao Matsushima 1, Kazuyuki Akagawa² 1. National Institute of Advanced Industrial.

MIT Optics & Quantum Electronics Group Seeding with High Harmonics Franz X. Kaertner Department of Electrical Engineering and Computer Science and Research.

A Thermospheric Lidar for He 1083 nm, Density and Doppler Measurements

V. Sonnenschein, I. D. Moore, M. Reponen, S. Rothe, K.Wendt.

Quenching of Fluorescence and Broadband Emission in Yb 3+ :Y 2 O 3 and Yb 3+ :Lu 2 O 3 3rd Laser Ceramics Symposium : International Symposium on Transparent.

Yb:YAG Regenerative Amplifier for A1 Ground Laser Hut Rui Zhang ACCL Division V, RF-Gun Group Nov 20, 2015 SuperKEKB Injector Laser RF Gun Review.

We have experimentally observed a similar qualitative behavior by measuring the ratio between the CW and ML intra-cavity powers as a function of Z for.

Oscillator stability & ASE Reduction

Laser System Upgrade Overview

TOWARD GENERATION OF HIGH POWER ULTRAFAST WHITE LIGHT LASER USING FEMTOSECOND TERAWATT LASER IN A GAS-FILLED HOLLOW-CORE FIBER Walid Tawfik Physics and.

Ultrashort pulsed laser technology for new detectors

Laser drilling of a Copper Mesh

Workshop for advanced THz and Compton X-ray generation

Space-time analogy True for all pulse/beam shapes

Laser-Plasma X-ray Source X-ray, λ~nm, >mJ, ~10μm ϕ ps

Formatvorlage des Untertitelmasters durch Klicken bearbeiten 1/27/15 Passively CEP-stable front end for optical frequency synthesis 1 Ultrafast Optics.

J. Corlett. June 16, 2006 A Future Light Source for LBNL Facility Vision and R&D plan John Corlett ALS Scientific Advisory Committee Meeting June 16, 2006.

The dye is a large molecule with a large number of closely spaced vibrational states – essentially a continuum of states. The pump pulse populates the.

Date of download: 6/1/2016 Copyright © 2016 SPIE. All rights reserved. (a) The schematic diagram and (b) the photograph of the graphene saturable absorber.

Nd:YAG Solid Laser Xiangyu Zhou 20. Nov Yb fiber laser system on the ground Menlo 1030nm oscillator Grating stretcher (Transmission) SOA pulse.

Picking the laser ion and matrix for lasing

L. Corner and T. Hird John Adams Institute for Accelerator Science, Oxford University, UK 1AAC, USA, 2016 The efficient generation of radially polarised.

Yb:YAG Regenerative Amplifier for A1 Ground Laser Hut Rui Zhang ACCL Division V, RF-Gun Group Nov 20, 2015 SuperKEKB Injector Laser RF Gun Review.

Mingyun Li & Kevin Lehmann Department of Chemistry and Physics

Single and dual wavelength Er:Yb double clad fiber lasers

Present myself and the group Present our current research on: “title”

Principle of Mode Locking

Kansas Light Source Laser System J. R. Macdonald Laboratory

Ken-Chia Chang, and Ming-Dar Wei* *

LCLS Injector Laser System Paul R. Bolton, SLAC April 24, 2002

Presentation transcript:

Formatvorlage des Untertitelmasters durch Klicken bearbeiten 1/26/15 1 kHz, multi-mJ Yb:KYW bulk regenerative amplifier 1 Ultrafast Optics and X-Ray Division, Center for Free-Electron Laser Science / DESY, Notkestrasse 85, Hamburg, Germany 2 Department of Physics and the Hamburg Centre for Ultrafast Imaging, University of Hamburg Luruper Chaussee 149, D Hamburg, Germany 3 Department of Electrical Engineering and Computer Science, MIT-RLE, Cambridge, Massachusetts 02139, USA Anne-Laure Calendron1,2, Huseyin Cankaya1,2, Franz Kärtner1,2,3 Characteristics: Cavity: - Dual-crystal resonator similar to Ref. [1] - Insensitive to variation of thermal lenses for fth = 280 – 800 nm Crystals: - 3 mm, 2%-Yb:KYW crystals - ng – cut, lasing on nm Pump: - Fiber coupled laser diode NA=0.15, MFD = 200 µm - Wavelength λ = 981 nm - Maximal pump power PP = 120 W Motivation Experimental set-upExperimental results References Conclusions High-energy lasers are sought for Pumping of Optical Parametric (Chirped Pulse) Amplifiers Micro-machining Surgery Aim at >5mJ, low repetition rate (~kHz) Design criteria: Distribution of thermal load Minimization of non-linearities  Solution: Regenerative amplifier with short crystals and increased pump spots Fig. 1: Layout of the resonator. [1] A.-L. Calendron, ”Dual-crystal Yb:CALGO high power laser and regenerative amplifier”, Opt. Express, (2013) [2] Eksma Website: [3] R. Peters, C. Kränkel, S. T. Fredrich-Thornton, K. Beil, K. Petermann, G. Huber, O. H. Heckl, C. R. E. Baer, C. J. Saraceno, T. Südmeyer, and U. Keller, “Thermal analysis and efﬁcient high power continuous-wave and mode-locked thin disk laser operation of Yb-doped sesquioxides” Appl Phys B 102, 509 (2011) [4] R. Peters, C. Kränkel, K. Petermann, and G. Huber, “Broadly tunable high-power Yb:Lu2O3 thin disk laser with 80% slope efficiency”, Opt. Express 15, 7075 (2007) [5] Roditi Website: Fig. 3: Variation of the beam size in the crystal versus thermal lens. Fig. 5: Tuning curve with beam quality M2 < 1.1 Small signal absorption: 60%. Fig. 4: Slope efficiency. Free running laser output wavelength: 1031 nm Fig. 6: Extraction in cavity-dumped operation for 850 ns extraction time, at 1 kHz and for quasi-CW pumping. Pulse duration (20 ns) corresponds to cavity round-trip. Limitation: pump power. - Demonstration of a high power laser head with two 2% doped Yb:KYW crystals - In CW operation: nearly 20 W output power from 2 crystals pumped with 123 W – free running wavelength: 1031 nm - In cavity dumped operation, extraction up to kHz - Seeded with 0.6 nJ energy, 6.5 mJ 1 kHz with 3.6 nm broad pulses supporting < 1 ps - Outlook: - White-light generation with compressed pulses - Scaling up to higher energies and higher average powers Seeded operation: Continuous-wave operation: κundoped [W/m/K] σemission [10-20 cm2] σabsoption [10-20 cm2] τ [µs] Δλemission [nm] Tab. 1: Material properties. Fig. 7: Spectra of the seed, in cavity-dumped and seeded operations. The gain narrowing after the regenerative amplifier corresponds to the overlap of seed and CD spectra W nm Fig. 8: Long-term measurement of the regenerative amplifier. RMS < 1% S Fig. 2: Variation of the waist at “S“ with the thermal lens. Constant spot sizes in the rest of the cavity. Of importance for: - Output beam: same parameters for thermal lenses between 280 mm and 800 mm. - Pumping in QCW or CW regimes possible Fig. 9: Pointing stability measurement of the regenerative amplifier. M2Xtal M3M5M6