F. Roeser, C. Jauregui, J. Limpert, and A. Tünnermann, 94 W 980 nm high brightness Yb-doped fiber laser, Opt. Express, vol.16, pp.17310-17318, 2008.
DOI : 10.1364/oe.16.017310

J. Saby, High Power IR, Green and UV Fiber Lasers, Lasers, Sources, and Related Photonic Devices, 2012.
DOI : 10.1364/filas.2012.fth5a.3

G. K. Samanta, S. C. Kumar, and M. Ebrahim-zadeh, Stable, 9.6 W, continuous-wave, single-frequency, fiber-based green source at 532 nm

. Lett, High NA fibers -a comparison of optical, thermal and mechanical properties of ultra low index coated fibers and air clad MOFs Kay Schuster a, Evidence of AlOHC responsible for the radiation-induced darkening in Yb doped fiber.Deschamps T1, vol.34, pp.8382-92, 2009.

R. C. Hanna, I. R. Percival, R. G. Perry, P. J. Smart, A. C. Suni et al., OSA/ASSL 1989 [ARM 89] Efficient 980-nm Operation of a Yb -Doped Silica Fiber Laser, Continuous-Wave Tunable and Superfluorescent Operation of a Monomode Ytterbium-Doped Fiber Laser D, vol.89, 1989.

, W single-transverse-mode Yb-doped double-clad fibre laser at 978

J. D. Zenteno, A. Minelly, A. J. Liu, S. G. Ellison, D. T. Crigler et al.,

A. Bruner, D. Eger, M. B. Oron, P. Blau, M. Katz et al., Temperature-dependent Sellmeier equation for the refractive index of stoichiometric lithium tantalate, Appl. Phys. Lett, vol.28, p.847, 1984.


I. Camlibel, J. Appl. Phys, vol.40, p.1690, 1969.

M. Castaing, F. Balembois, P. Georges, T. Georges, K. Schaffers et al., Diode-pumped Nd:YVO4/Yb:S-FAP laser emitting at 985 and 492.5 nm, Opt. Lett, vol.33, pp.1234-1236, 2008.
DOI : 10.1364/ol.33.001234

URL : https://hal.archives-ouvertes.fr/hal-00533391

L. A. Juan and . Chilla,

D. Stuart and . Butterworth,

J. P. Charles,

A. L. Caprara, High-power optically pumped semiconductor lasers, Solid State Lasers XIII: Technology and Devices, vol.5332, 2004.

A. Dolev, O. Gananypadowicz, A. Gayer, J. Arie, G. Mangin et al., Site internet commercial Coherent (2014) nonlinear optical properties of MgO:LiTaO3, I, Applied Physics B, vol.96, issue.2-3, pp.423-432, 2009.

T. Hwan-hong-lim, S. Katagai, T. Kurimura, K. Shimizu, N. Noguchi et al., Thermal performance in high power shg characterized by phase-matched calorimetry, Norikatsu Moi and Ichiro Shoji, vol.19, issue.23, p.22588, 2011.

J. Zhang, Y. Chen, F. Lu, W. Lu, W. Dang et al., Effect of MgO doping of periodically poled lithium niobate on second-harmonic generation of femtosecond laser pulses, Appl. Opt, vol.46, pp.7792-7796, 2007.

, Emir Karamehmedovi?

T. Martin, P. Andersen, and . Tidemand-lichtenberg, 300 mW of coherent light at 488 nm using a generic approach, Proc. SPIE6875, Nonlinear Frequency Generation and Conversion: Materials, Devices, and Applications VII, vol.687512, 2008.


. Ppmgslt, &. F. Ppmgln, I. Kontur, Y. Dajani, R. J. Lu et al., Frequency doubling of a CW fiber laser using PPKTP, vol.15, 2007.

S. Kumar, G. K. Samanta, and M. Ebrahim-zadeh, High-power, single-frequency, continuous-wave second-harmonic-generation of ytterbium fiber laser in PPKTP and MgO:sPPLT, Opt. Express, vol.17, pp.13711-13726, 2009.

]. S. Kumar, G. K. Samanta, K. Devi, and M. Ebrahim-zadeh, High-efficiency, multicrystal, single-pass, continuous-wave second harmonic generation, Opt. Express, vol.19, pp.11152-11169, 2011.
DOI : 10.1364/oe.19.011152

G. Li, Y. Cui, and J. Wang, Photorefractive inhibition of second harmonic generation in periodically poled MgO doped LiNbO3 waveguide, Opt. Express, vol.21, pp.21790-21799, 2013.

O. A. Louchev, N. E. Yu, S. Kurimura, and K. Kitamura,

, Phys. Lett, vol.87, p.131101, 2005.

G. D. Miller, R. G. Batchko, W. M. Tulloch, D. R. Weise, M. M. Fejer et al.,

. Byer, 42%-efficient single-pass cw second-harmonic generation in periodically poled lithium niobate, InGaN-based 518 and 488 nm laser diodes on c-plane GaN substrate, vol.22, pp.1834-1836, 1997.

T. Miyoshi, *. , S. Masui, T. Okada, and T. Yanamoto,

, , 2010.

G. K. Samanta, S. Kumar, M. Mathew, C. Canalias, and V. ,

F. Pasiskevicius, M. Laurell, and . Ebrahim-zadeh, High-power, continuous-wave, second-harmonic generation at 532 nm in periodically poled KTiOPO4, Opt. Lett, vol.33, pp.2955-2957, 2008.

G. K. Samanta, S. Kumar, and M. Ebrahim-zadeh, Stable, 96 W, continuous-wave, single-frequency, fiber-based green source at 532 nm, vol.34, 2009.

, Sven Schwertfeger; Martin Maiwald; Reiner Güther; Bernd Sumpf; Katrin Paschke; Christian Dzionk

, Günther Tränkle Proc. SPIE 6184, Semiconductor Lasers and Laser Dynamics, vol.II, p.61840, 2006.

, Phys. Rev. B, vol.48, p.15613, 1993.

;. B. Betzler, M. D. Stuart, S. Feit, A. M. Herman, B. W. Rubenchik et al., J. Opt. Soc. Am. B, vol.13, issue.2, 1996.

V. Sergey, S. Tovstonog, I. Kurimura, K. Suzuki, and . Takeno,

S. Moriwaki, N. Ohmae, N. Mio, and T. Katagai, Thermal effects in high-power CW second harmonic generation in Mg-doped stoichiometric lithium tantalate, WAA 13] Niklas Waasem, Ashot Markosyan, Martin M. Fejer, and Karsten Buse, vol.16, pp.2953-2956, 2008.

, microjoules et une puissance crête de 6,7 kW. Ceci représente une efficacité de 33% vis-à-vis

, Les niveaux de puissance et d'énergie ainsi démontrés à 325 nm sont inédits dans le cas des

, All-fiber Yb-doped CW and pulsed laser sources operating near 980nm, 2011.

H. Chen, High-Repetition-Rate, Single-Pass ThirdHarmonic Generation of 354 nm Ultraviolet Laser with 51.5% Efficiency Hailong Chen, Qiang Liu, Ping Yan, Qirong Xiao and Mali Gong, Appl. Phys. Express, vol.5, p.92702, 2012.

C. Fiber1, Z. Y. Dong, *. , S. Z. Zou, Z. H. Han et al.,

J. M. Lin and . Li, Laser Physics, vol.21, issue.3, pp.536-539, 2011.

F. Juvalta, M. Jazbinsek, P. Günter, and K. Kitamura, Electrooptical properties of near-stoichiometric and congruent lithium tantalate at ultraviolet wavelengths, J. Opt. Soc. Am. B, vol.23, pp.276-281, 2006.

A. Gatto, R. Thielsch, J. Heber, N. Kaiser, D. Ristau et al.,

A. and C. Amra, High-performance deep-ultraviolet optics for freeelectron lasers, Appl. Opt, vol.41, pp.3236-3241, 2002.
URL : https://hal.archives-ouvertes.fr/hal-01324126

H. Hong, Q. Liu, L. Huang, and M. Gong, Improvement and formation of UV-induced damage on LBO crystal surface during long-term high-power third-harmonic generation, Opt. Express, vol.21, pp.7285-7293, 2013.

C. Jung, W. Shin, B. Yu, Y. L. Lee, and Y. Noh, Enhanced 355-nm generation using a simple method to compensate for walk-off loss, Opt. Express, vol.20, pp.941-948, 2012.

. Nm-picosecond-ytterbium-fiber, S. Laser, J. Karirinne, T. Konttinen, A. B. Jouhti et al., Solid State Lasers and Amplifiers, Proceedings of SPIE, vol.5460, 2004.

J. Lhermite, C. Lecaplain, G. Machinet, R. Royon, A. Hideur et al., Mode-locked 0.5 ?J fiber laser at 976 nm, Opt. Lett, vol.36, issue.19, pp.3819-3821, 2011.

, -W average-power, high-energy nanosecond fiber amplifier, j. limpert1,s. h¨ofer, a. liem, h. zellmer, a. t ¨unnermann, s. knoke, h. voelckel, Appl. Phys. B, vol.75, pp.477-479, 2002.

, Laser-induced breakdown and damage generation by nonlinear frequency conversion in ferroelectric crystals: Experiment and theory, LOU, vol.13

O. A. Louchev, . Hatano, ;. Hideki, . Saito, ;. Norihito et al., Journal of Applied Physics, vol.114, pp.203101-203101, 2013.

J. Meyn and M. M. Fejer, Tunable ultraviolet radiation by second-harmonic generation in periodically poled lithium tantalate, OPTICS LETTERS, vol.22, issue.16, 1997.

, Characteristics of Q-Switched Cladding-Pumped Ytterbium-Doped Fiber Lasers with Different High-Energy Fiber Designs

A. Alvarez-chavez, J. Nilsson, W. A. Clarkson, P. W. Turner, D. J. Richardson et al., IEEE JOUNRNAL OF QUANTUM ELECTRONICS, vol.37, issue.2, 2001.

J. Saby, High Power IR, Green and UV Fiber Lasers, Lasers, Sources, and Related Photonic Devices, 2012.

, Extractable energy from ytterbium doped high energy pused fiber amplifiers and lasers

E. Avraham, R. Lavi-;-fabian-stutzki, F. Jansen, T. Eidam, A. Steinmetz et al., / OPTICS LETTERS [WAG 98] Multiple pulse nanosecond laser induced damage study in LiB3O5 crystals, Natoli1 and Mireille Commandré1, vol.2, p.34, 1998.

, nm third-harmonic generation with effective walk-off compensation of LBO Xingpeng Yan1,2,3, Qiang Liu2,3, Chuang Pei1, Dongsheng Wang2 and Mali Gong2 [WAG 10] rank, Opt. Express, vol.16, pp.26791-26798, 2010.

, Dynamic Characteristics of Double-Clad Fiber Amplifiers for High-Power Pulse Amplification, Yong Wang, and Hong Po, JOURNAL OF LIGHTWAVE TECHNOLOGY, vol.21, issue.10, 2003.

Y. Yamashita, M. Kuwabara, K. Torii, and H. Yoshida, A 340-nm-band ultraviolet laser diode composed of GaN well layers, Opt. Express, vol.21, pp.3133-3137, 2013.

J. Boullet, R. Dubrasquet, C. Médina, R. Bello-doua, N. Traynor et al., High-brightness fiber laser pumped 68 fs-2.3 W Kerr-lens mode-locked Yb:CaF2 oscillator, Millijoule-class Yb-doped fiber laser system operating at 977 nm, vol.35, p.1650, 2010.

M. Castaing and ;. Traynor,

E. Cormier-photonics-west, ;. J. Boullet, R. Dubrasquet, C. Médina, R. Bello-doua et al., Yb-doped fiber laser system generating 12 ns, 0.7 mJ pulses at 82 kHz at 977 nm, Proc. SPIE 8961, Fiber Lasers XI: Technology, Systems, and Applications, 89611Q, pp.2-7, 2010.

J. Boullet, R. Dubrasquet, C. Médina, R. Bello-doua, N. Traynor et al., Visible and Infrared Sources based on Three-Level Ytterbium-doped Fiber Lasers, Cormier Fiber Laser Applications (FILAS) [FThC5, pp.16-17, 2010.
DOI : 10.1364/filas.2011.fthc5

, Pompage haute brillance des matériaux lasers dopés Yb : fort gain et impulsions sub 100 fs dans l'Yb:CaF2

G. Machinet, P. Sévillano, R. Dubrasquet, J. Lhermite, G. Andriukaitis et al., Cormier Journées Nationales des Cristaux pour l'Optique, JNCO2013, 2013.