Presentation is loading. Please wait.

Presentation is loading. Please wait.

Injection seeded ns-pulsed Nd:YAG laser at 1116 nm for Fe-Lidar

Published byFrançoise Benoît Modified over 5 years ago

Similar presentations

Presentation on theme: "Injection seeded ns-pulsed Nd:YAG laser at 1116 nm for Fe-Lidar"— Presentation transcript:

1 Injection seeded ns-pulsed Nd:YAG laser at 1116 nm for Fe-Lidar
> Lecture > Author • Document > Date Injection seeded ns-pulsed Nd:YAG laser at 1116 nm for Fe-Lidar Alexander Fischer1, Peter Mahnke1, Daniel Sauder1, Matthias Damm1, Hans Christian Büdenbender2 , Jochen Speiser1 1DLR Stuttgart Institute for Technical Physics 2DLR Oberpfaffenhofen Institute for Atmospherical Physics

2 Motivation Alima: Airborne Lidar for studying the middle atmosphere
> Lecture > Author • Document > Date Motivation Alima: Airborne Lidar for studying the middle atmosphere Cooperation with DLR Oberpfaffenhofen PA-LID Iron in the upper atmosphere ( km) Fluorescence line of 372 nm suitable for resonance Lidar Analysis of the line gives information about air velocity, temperature, gravity waves Goal: compact, airborne system Gelbwachs J., Appl. Opt. 33, 7151 (1994) Gardner et al, Geophys. Res. Lett. 27, 1199 (2001) Chu et al, Appl. Opt. 41, 4400 (2002) Kaifler et al. ;New Lidar Systems at the German Aerospace Center, LPMR 2015

3 Generation of 372 nm: existing system
> Lecture > Author • Document > Date Generation of 372 nm: existing system 100 mJ ~60 ns 34 Hz 3 W 744 nm 2w 372 nm Alexandrite laser single frequency Chu et al., Appl. Opt. 21, 4400 (2002) developed by the NCAR Disadvantage: small emission cross section, needs heating strong pumping source needed

4 Generation of 372 nm: OPO 532 nm 1116 nm 558 nm 1064 nm 2w 2w 3w
> Lecture > Author • Document > Date Generation of 372 nm: OPO 532 nm 1116 nm 558 nm 1064 nm 2w 2w 3w 372 nm OPO >50 mJ single frequency Nd:YAG 1 J, 100 Hz, 10 ns commercially available disadvantages: not very efficient danger of damage of optics due to high pulse energies

5 Generation of 372 nm: resonator at 1116 nm
> Lecture > Author • Document > Date Generation of 372 nm: resonator at 1116 nm 1116 nm 2w 3w single frequency >15 mJ, 100 Hz, <100 ns amplifier system >150 mJ 372 nm, >50 mJ can be realized very compact avoids very high pulse energies small cooling system required

6 Nd:YAG laser line at 1116 nm emission cross sections:
> Lecture > Author • Document > Date Nd:YAG laser line at 1116 nm emission cross sections: challenges with 1116 nm: ~7 times lower amplification than with 1064 nm supression of 1064 nm s1064 = 2,8*10-19 cm² s1116 = 0,42*10-19 cm² Alexandrite s744 = 0,07*10-19 cm² (295 K) and 0,30*10-19 cm² (463 K) Marling, IEEE J. Quant. Electron, 14, 56 (1978) Wang et al.; Appl. Phys B (2011) 104:45–52 Huan et al.; Chin. Phys. B Vol. 21, No. 10 (2012) Zhang et al.; CHIN. PHYS. LETT. Vol. 30, No. 10 (2013)

7 Realisation of the resonator
> Lecture > Author • Document > Date Realisation of the resonator to experiment/ frequency conversion etalon l/4 plate l/4 plate TFP end mirror Pockels cell end mirror pump chamber with Nd:YAG crystal seed laser diode 1116 nm cw, 5 mW, single frequency side pumped setup injection seeded resonator length ~110 cm pump duration Hz

8 Injection Seeding etalon l/4 plate l/4 plate TFP end mirror
> Lecture > Author • Document > Date Injection Seeding etalon l/4 plate l/4 plate TFP end mirror Pockels cell end mirror pump chamber with Nd:YAG crystal seed laser no stabilization (bad parameters) (2 modes) Need for stabilization of the resonator length to get proper seeding single frequency

9 Feedback-looped Stabilzation
> Lecture > Author • Document > Date Feedback-looped Stabilzation end mirror with piezo l/4 plate l/4 plate photodiode TFP pump chamber with Nd:YAG crystal seed laser Build-up-time feedback control Folie mit vorher kombinieren

10 Output power and beam quality
> Lecture > Author • Document > Date Output power and beam quality M² ~ 1,1 maximum pulse energy ~ nm nm (max. efficiency 35%) output coupling ~10% pulse length 80 ns

11 Further Work implementation of a end pumped resonator
> Lecture > Author • Document > Date Further Work implementation of a end pumped resonator

Download ppt "Injection seeded ns-pulsed Nd:YAG laser at 1116 nm for Fe-Lidar"

Similar presentations

10W Injection-Locked CW Nd:YAG laser

10W Injection-Locked CW Nd:YAG laser
Positronium Rydberg excitation in AEGIS Physics with many positrons International Fermi School 07-17 July 2009 – Varenna, Italy The experimental work on.

Positronium Rydberg excitation in AEGIS Physics with many positrons International Fermi School July 2009 – Varenna, Italy The experimental work on.
P.M. Paul, L.Vigroux, G. Riboulet, F.Falcoz. 2 Main Limitation in High gain Amplifier: Gain Narrowing Ti:Sa Pockels cell FWHM

P.M. Paul, L.Vigroux, G. Riboulet, F.Falcoz. 2 Main Limitation in High gain Amplifier: Gain Narrowing Ti:Sa Pockels cell FWHM
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.

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.
Visible Laser Light — Do Not Stare into Beam or View Directly with Optical Instruments Initials: __________Date: __________ CW power: ______________WType:

Visible Laser Light — Do Not Stare into Beam or View Directly with Optical Instruments Initials: __________Date: __________ CW power: ______________WType:
Measured parameters: particle backscatter at 355 and 532 nm, particle extinction at 355 nm, lidar ratio at 355 nm, particle depolarization at 355 nm, atmospheric.

Measured parameters: particle backscatter at 355 and 532 nm, particle extinction at 355 nm, lidar ratio at 355 nm, particle depolarization at 355 nm, atmospheric.
Invisible and Visible Laser Radiation — Avoid Direct Eye Exposure Initials: __________Date: __________ CW power: ______________WType: _______________ Pulse.

Invisible and Visible Laser Radiation — Avoid Direct Eye Exposure Initials: __________Date: __________ CW power: ______________WType: _______________ Pulse.
Lecture 38 Lasers Final Exam next week. LASER L ight A mplification by S timulated E mission of R adiation.

Lecture 38 Lasers Final Exam next week. LASER L ight A mplification by S timulated E mission of R adiation.
Invisible and Visible Laser Radiation — Avoid Direct Eye Exposure Initials: __________Date: __________ CW power: ______________WType: _______________ Pulse.

Invisible and Visible Laser Radiation — Avoid Direct Eye Exposure Initials: __________Date: __________ CW power: ______________WType: _______________ Pulse.
Updates on Single Frequency 2 µm Laser Sources

Updates on Single Frequency 2 µm Laser Sources
TCT+, eTCT and I-DLTS measurement setups at the CERN SSD Lab

TCT+, eTCT and I-DLTS measurement setups at the CERN SSD Lab
SAPPHiRE workshop, CERN 19 th Feb 2013 A SAPPHiRE Laser? Laura Corner Lasers for Accelerators group (L4A) John Adams Institute for Accelerator Science,

SAPPHiRE workshop, CERN 19 th Feb 2013 A SAPPHiRE Laser? Laura Corner Lasers for Accelerators group (L4A) John Adams Institute for Accelerator Science,
Laser Notcher Pulse Energy Requirements & Demonstration Experiment David Johnson, Todd Johnson, Vic Scarpine.

Laser Notcher Pulse Energy Requirements & Demonstration Experiment David Johnson, Todd Johnson, Vic Scarpine.
ILE OSAKA New Concept of DPSSL - Tuning laser parameters by controlling temperature - Junji Kawanaka ILE OSAKA US-Japan Workshop on Laser-IFE 21-22 March.

ILE OSAKA New Concept of DPSSL - Tuning laser parameters by controlling temperature - Junji Kawanaka ILE OSAKA US-Japan Workshop on Laser-IFE March.
Siegfried Schreiber, DESY The TTF Laser System Laser Material Properties Conclusion? Issues on Longitudinal Photoinjector.

Siegfried Schreiber, DESY The TTF Laser System Laser Material Properties Conclusion? Issues on Longitudinal Photoinjector.
The ILC Laser-wire system Sudhir Dixit The John Adams Institute University of Oxford.

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

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,
October 16-18, 2012Working Group on Space-based Lidar Winds 1 AEOLUS STATUS Part 1: Design Overview.

October 16-18, 2012Working Group on Space-based Lidar Winds 1 AEOLUS STATUS Part 1: Design Overview.
Quantum Noise Measurements at the ANU Sheon Chua, Michael Stefszky, Conor Mow-Lowry, Sheila Dwyer, Ben Buchler, Ping Koy Lam, Daniel Shaddock, and David.

Quantum Noise Measurements at the ANU Sheon Chua, Michael Stefszky, Conor Mow-Lowry, Sheila Dwyer, Ben Buchler, Ping Koy Lam, Daniel Shaddock, and David.
Status of the advanced LIGO laser O. Puncken, L. Winkelmann, C. Veltkamp, B. Schulz, S. Wagner, P. Weßels, M. Frede, D. Kracht.

Status of the advanced LIGO laser O. Puncken, L. Winkelmann, C. Veltkamp, B. Schulz, S. Wagner, P. Weßels, M. Frede, D. Kracht.

Similar presentations

Ads by Google