OSA's Digital Library

Optics Express

Optics Express

  • Editor: Andrew M. Weiner
  • Vol. 21, Iss. 6 — Mar. 25, 2013
  • pp: 7156–7161
« Show journal navigation

Wavelength switchable high-power diode-side-pumped rod Tm:YAG Laser around 2µm

Caili Wang, Shifeng Du, Yanxiong Niu, Zhichao Wang, Chao Zhang, Qi Bian, Chuan Guo, Jialin Xu, Yong Bo, Qinjun Peng, Dafu Cui, Jingyuan Zhang, Wenqiang Lei, and Zuyan Xu  »View Author Affiliations


Optics Express, Vol. 21, Issue 6, pp. 7156-7161 (2013)
http://dx.doi.org/10.1364/OE.21.007156


View Full Text Article

Acrobat PDF (823 KB)





Browse Journals / Lookup Meetings

Browse by Journal and Year


   


Lookup Conference Papers

Close Browse Journals / Lookup Meetings

Article Tools

Share
Citations

Abstract

We report a high-power diode-side-pumped rod Tm:YAG laser operated at either 2.07 or 2.02 µm depending on the transmission of pumped output coupler. The laser yields 115W of continuous-wave output power at 2.07 µm with 5% output coupling, which is the highest output power for all solid-state 2.07 μm cw rod Tm:YAG laser reported so far. With an output coupler of 10% transmission, the center wavelength of the laser is switched to 2.02 μm with an output power of 77.1 W. This is the first observation of high-power wavelength switchable diode-side-pumped rod Tm:YAG laser around 2 µm.

© 2013 OSA

1. Introduction

The high-power lasers at 2 µm have attracted great research attention and it have been extensively investigated recently because of its attractive applications in the areas of medical treatment, optical communications and effective pump sources for 3 – 5 µm optical parametric oscillators (OPOs) [1

1. J. Yu, B. C. Trieu, E. A. Modlin, U. N. Singh, M. J. Kavaya, S. Chen, Y. Bai, P. J. Petzar, and M. Petros, “1 J/pulse Q-switched 2 μm solid-state laser,” Opt. Lett. 31(4), 462–464 (2006). [CrossRef] [PubMed]

4

4. L. J. Lia, B. Q. Yao, Y. L. Ju, and Y. Z. Wang, “8.30 μm Singly Resonant ZnGeP2 Optical Parametric Oscillators Pumped by a Tm,Ho:GdVO4 Laser,” Laser Phys. 19(10), 1957–1959 (2009). [CrossRef]

]. One way to generate high power laser around 2 µm is by means of rare-earth ion doped crystals, including Tm3+, Ho3+, Tm3+-Ho3+, Cr3+-Tm3+-Ho3+ lasers [5

5. M. Schellhorn, S. Ngcobo, and C. Bollig, “High-power diode-pumped Tm:YLF slab laser,” Appl. Phys. B 94(2), 195–198 (2009). [CrossRef]

, 6

6. C. T. Wu, Y. L. Ju, Z. G. Wang, Q. Wang, C. W. Song, and Y. Z. Wang, “Diode-pumped single frequency Tm:YAG laser at room temperature,” Laser Phys. Lett. 5(11), 793–796 (2008). [CrossRef]

]. This paper focuses on the all-solid-state Tm3+ doped YAG lasers. The use of Tm3+ doped YAG has characteristics of long fluorescence lifetime, broader absorption and emission spectra, cross-relaxation introduced high quantum efficiency etc. and therefore it can become good candidate for high power lasing at 2 μm [7

7. A. Sato, K. Asai, and T. Itabe, “Double-pass-pumped Tm:YAG laser with a simple cavity configuration,” Appl. Opt. 37(27), 6395–6400 (1998). [CrossRef] [PubMed]

]. Besides, the absorption band of Tm3+ ions near 785 nm matches well with the commercially available laser diodes. Among various host matrices, YAG crystal posses the advantages of large heat conductivity and high mechanical strength, which allows high power operation with reduced risk of fracture [8

8. O. A. Buryy, D. Y. Sugak, S. B. Ubizskii, I. I. Izhnin, M. M. Vakiv, and I. M. Solskii, “The comparative analysis and optimization of the free-running Tm3+:YAP and Tm3+:YAG microlasers,” Appl. Phys. B 88(3), 433–442 (2007). [CrossRef]

, 9

9. Y. L. Ju, Q. Wang, C. T. Wu, Z. G. Wang, and Y. Z. Wang, “Lasing Characteristics of a Single-Frequency Tm:YAG Laser,” Laser Phys. 19(6), 1216–1219 (2009). [CrossRef]

]. Thus, Tm:YAG material is a promising material for obtaining high power laser around 2 µm.

In the Tm3+ doped YAG crystal, the Tm3+ ions are excited into the 3H4 state from 3H6 state by absorbing pump radiation at ~785 nm, and the ions then relax down to the upper lasing level 3F4. The laser radiation at 2 µm takes place between the lower Stark level of 3F4 and the higher Stark level of 3H6, which include 610 cm−1, 730 cm−1 [10

10. W. Koechner, Solid-State Laser Engineering, 6th Revised and Updated Edition (Springer, 2006), Chap. 8.

, 11

11. M. Eichhorn, “Quasi-three-level solid-state lasers in the near and mid infrared based on trivalent rare earth ions,” Appl. Phys. B 93(2-3), 269–316 (2008). [CrossRef]

]. When the ions transition from lowest Stark sub-level in 3F4 at 5556cm−1 to 3H6 level, resulting in the possible laser emissions at 2.02 μm, 2.07 μm, respectively, as shown in Fig. 1
Fig. 1 Energy level diagram of Tm: YAG lasers.
.

High power Tm:YAG lasers at 2.02 μm have been reported by several groups. E. C. Honea et al. reported an 115 W continuous wave (cw) Tm: YAG laser with diode laser (LD) end-pumped structure under 3°C with the coolant mixture of 90% and water 10% alcohol [12

12. E. C. Honea, R. J. Beach, S. B. Sutton, J. A. Speth, S. C. Mitchell, J. A. Skidmore, M. A. Emanuel, and S. A. Payne, “115-W Tm:YAG Diode-Pumped Solid-State Laser,” IEEE J. Quantum Electron. 33(9), 1592–1600 (1997). [CrossRef]

]. K. S. Lai et al. achieved an 150 W cw LD side-pumped rod Tm:YAG laser under −10°C with the mixture of water and glycerol as the coolant [13

13. K. S. Lai, W. J. Xie, R. F. Wu, Y. L. Lim, E. Lau, L. Chia, and P. B. Phua, “A 150 W 2-micron diode-pumped Tm:YAG laser,” in Conference on Advanced Solid-state Lasers, (Optical Society of America, 2002), Vol. 68, 535–539.

]. Unfortunately, these lasers were all operated under low temperature, which may lead to freezing of the coolant or condensation at the rod surfaces. Our group has demonstrated the generation of cw 200 W output power in Tm:YAG laser at 2.02 µm under 8°C water-cool environment in 2011 [14

14. D. Cao, Q. Peng, S. Du, J. Xu, Y. Guo, J. Yang, Y. Bo, J. Zhang, D. Cui, and Z. Xu, “A 200W diode-side-pumped CW 2 μm Tm:YAG laser with water cooling at 8°C,” Appl. Phys. B 103(1), 83–88 (2011). [CrossRef]

], while a Q-switched Tm:YAG laser at 2.02 µm with output power of 171.4W under operated temperature of 8°C was also reported [15

15. D. Cao, S. Du, Q. Peng, J. Xu, Y. Bo, Y. Guo, J. Zhang, D. F. Cui, and Z. Y. Xu, “171.4 W Diode-Side-Pumped Q-Switched 2µm Tm:YAG Laser with a 10 kHz Repetition Rate,” Chin. Phys. Lett. 29(4), 044210 (2012). [CrossRef]

].

As for rod Tm:YAG laser at 2.07 μm, very little has been published. With Ti:sapphire laser pumping, R. C. Stoneman et al. reported a tunable Tm:YAG laser from 1.9 to 2.16 µm and the output-powers at 2.07 µm was only 280 mW [16

16. R. C. Stoneman and L. Esterowitz, “Efficient, broadly tunable, laser-pumped Tm:YAG and Tm:YSGG cw lasers,” Opt. Lett. 15(9), 486–488 (1990). [CrossRef] [PubMed]

].

For applications such as free-space optical communication, long-range communication requiring minimal atmospheric attenuation, the longer wavelength around 2 µm is superior [17

17. S. W. Henderson, P. J. M. Suni, C. P. Hale, S. M. Hannon, J. R. Magee, D. L. Bruns, and E. H. Yuen, “Coherent laser radar at 2 µm using solid-state lasers,” IEEE Trans. Geosci. Rem. Sens. 31(1), 4–15 (1993). [CrossRef]

]. Specially, the Tm:YAG laser with longer wavelength has less absorption loss in the ZnGeP2 (ZGP) crystal [18

18. V. Petrov, Y. Tanaka, and T. Suzuki, “Parametric Generation of 1-ps Pulses Between 5 and 11 µm with a ZnGeP2 Crystal,” IEEE J. Quantum Electron. 33(10), 1749–1755 (1997). [CrossRef]

].Therefore, compared with 2.02 µm, the Tm:YAGlaser at 2.07µm is more suitable for pumping ZGP-OPO.

In this paper, we report a high-power wavelength switchable LD side-pumped rod Tm:YAG laser system around 2 µm under 8°C water-cool environment. The system operates at either 2.07 or 2.02 µm depending on the transmission of the output coupler. The maximum cw output power at 2.02 µm is 77.1 W with a coupler of 10% transmission, while the maximum cw output power at 2.07 µm is up to 115 W by using a coupler of 5% transmission. To our knowledge, this is the first demonstration of wavelength switchable LD side-pumped 2 μm rod Tm:YAG laser with an output power over 100 W at 2.07 μm.

2. Experiment and result

The high-power rod Tm:YAG laser system around 2 µm is designed with two-rod scheme, in which two identical LD side pumping laser modules are employed. The experimental setup for the high-power rod Tm:YAG laser setup is shown in Fig. 2
Fig. 2 Schematic of the rod Tm:YAG laser around 2 µm
. The system adopts a Plano-Plano symmetrical cavity.

There were five diode arrays in each laser module and each diode array consists of twelve diodes operating in cw-mode at wavelength of 785 nm and the total pump power is 1200 W. The rod Tm:YAG(doped with 3.5% Tm) used in our experiment is 4 mm in diameter and 69 mm in length with screw threads fabricated on the side surface with a 0.6 mm screw-pitch and a 0.1 mm depth to increase surface area for better cooling. Each end-face of the rod is bonded with an 18 mm un-doped YAG, which is especially necessary for reducing the reabsorption losses in the unpumped region for the side-pumping configuration and for reducing the chances of thermal fracture and lensing owing to bulging of the rod surfaces. The rod Tm:YAG- is cooled to 8°C by de-ionized water. M1 and M2 are rear mirror and output coupler (OC), respectively. M1 is HR-coated with reflectivity R > 99.5% at 2 μm, and two output coupler mirrors M2 are coated with transmission Toc = 10% or 5% around 2 μm for wavelength switching. L1 and L3 are the distances between the M1 to laser module 1 and the M2 to laser module 2, respectively. L2 is the distance between two laser modules.

In order to design an optimum laser cavity, we measured the thermal focus length of each laser module as a function of LD pump power. The typical result is shown in the Fig. 3
Fig. 3 The thermal focus length of a single laser module versus diode-pump power
. The thermal focus length fT decreases with the increase of LD pump power, and fT is ~109 mm at pump power of 594 W.

For obtaining high output power with high beam quality, the cavity parameters are optimized by computer simulation using ABCD propagation matrix formula for the fundamental mode. Figure 4
Fig. 4 Stability-zone calculations for the fundamental mode beam radius at the center of laser rod of laser module 2 as a function of thermal focal length.
shows the simulation result with L1 = L3 = 25 cm and L2 = 50 cm for the calculated fundamental mode beam radius at the center of laser rod of laser module 2 as a function of thermal focal length. The laser system operates in the stable region under total LD pump power of 1,188 W, which corresponds to a thermal focus length around 109 mm according to the Fig. 3.

The output power of the rod Tm:YAG lasers at 2 μm is measured with a power meter (Ophir F300A-SH). The dependence of laser output power on the LD input power is shown in Fig. 5
Fig. 5 Output power of rod Tm:YAG laser versus diode pumping power
. The laser threshold occurs at about 432 W of diode-pumping power for Toc = 5%, and the maximum output power is up to 115 W under total LD pump power of 1,188 W at a cooling temperature of 8°C for the rod Tm:YAGs. While the laser threshold is around 619 W for Toc = 10%, and the maximum output power is up to 77.1 W under total LD pump power of 1,188W. Compared with Toc = 10%, the laser threshold for Toc = 5% is lower, the conversion efficiency is higher and higher output power can be achieved. It is worth noting that the laser output power for both output couplers depends linearly on the pump power when the pump power is below 792 W. The slope efficiency is about 22.5% with Toc = 5% and 21.1% with Toc = 10%, respectively.

The emission wavelengths of the 2 μm rod Tm:YAG laser with different Toc are recorded with an spectrometer (NIRQuest256-2.5, Ocean Optics). The laser spectra at maximum output power are shown in Fig. 6
Fig. 6 Spectra of rod Tm:YAG laser with different output couplings. The central wavelength is 2.07 μm for the one with Toc = 5% and 2.02 μm for the one with Toc = 10%
. It can be seen from Fig. 6 that the central wavelength of the laser with Toc = 5% is located at 2.07 μm at maximum output power of 115W. The wavelength is shifted to 2.02 μm when the output coupler is switched from Toc = 5% to 10%. The dependence of the laser wavelength on the Toc is attributed to reabsorption effect of quasi-three-level laser system [19

19. J. Kong, D. Y. Tang, J. Lu, and K. Ueda, “Random-wavelength solid-state laser,” Opt. Lett. 29(1), 65–67 (2004). [CrossRef] [PubMed]

, 20

20. H. H. Yu, Z. B. Pan, H. J. Zhang, Z. Wang, J. Wang, and M. Jiang, “Efficient Tm:LuVO₄ laser at 1.9 μm,” Opt. Lett. 36(13), 2402–2404 (2011). [CrossRef] [PubMed]

]. With the same pump power, a lower Toc would result in a higher intracavity intensity. As a result, the lower laser sub-level within 3H6 ground state manifold has higher reabsorption loss and therefore, the higher Stark sub-level within 3H6 ground state manifold has a lower laser threshold and longer laser wavelength.

The value of beam quality M2 can be derived from the measured beam profiles at various positions using a Pyro-III infrared CCD camera. Figure 7
Fig. 7 Beam quality factor of a 2.07μm rod Tm:YAG laser measured at an output power of 115W
shows M2 value of a 2.07 μm rod Tm:YAG laser measured at an output power of 115 W. The M2x and M2y factors are found to be about 15.2 and 14.7, respectively, corresponding to an average value of M2 = 15.

The laser power stability is monitored at the full output power. Figure 8
Fig. 8 Stability of a 2.07μm rod Tm:YAG laser measured at an output power of 115W
shows the measurement result for the 2.07 μm rod Tm:YAG laser. It is found that, for a test interval of 30 min, the fluctuation of output power is less than ± 3%.

3. Conclusions

In summary, we demonstrate here for the first time the high-power wavelength switchable LD-side-pumped Tm:YAG laser around 2 µm. The laser central wavelength is switchable between 2.07 and 2.02 µm by means of different OC transmission. The maximum output power at 2.07 µm is up to 115 W for Toc = 5%. This is, to the best of our knowledge, the highest power reported so far for a rod Tm:YAG laser at 2.07 µm. The maximum output power at 2.02 µm is 77.1 W for Toc = 10%. The novel spectral properties of the laser could be attributed to the reabsorption of light in the rod Tm:YAG laser medium.

Acknowledgments

The work was carried out under the auspices of the National High Technology Research and Development Program, the State Key Program for Basic Research of China and the Knowledge Innovation program of Chinese Academy of Sciences.

References and links

1.

J. Yu, B. C. Trieu, E. A. Modlin, U. N. Singh, M. J. Kavaya, S. Chen, Y. Bai, P. J. Petzar, and M. Petros, “1 J/pulse Q-switched 2 μm solid-state laser,” Opt. Lett. 31(4), 462–464 (2006). [CrossRef] [PubMed]

2.

P. J. M. Suni and S. W. Henderson, “1-mJ/pulse Tm:YAG laser pumped by a 3-W diode laser,” Opt. Lett. 16(11), 817–819 (1991). [CrossRef] [PubMed]

3.

T. Yokozawa and H. Hara, “Laser-diode end-pumped Tm(3+):YAG eye-safe laser,” Appl. Opt. 35(9), 1424–1426 (1996). [CrossRef] [PubMed]

4.

L. J. Lia, B. Q. Yao, Y. L. Ju, and Y. Z. Wang, “8.30 μm Singly Resonant ZnGeP2 Optical Parametric Oscillators Pumped by a Tm,Ho:GdVO4 Laser,” Laser Phys. 19(10), 1957–1959 (2009). [CrossRef]

5.

M. Schellhorn, S. Ngcobo, and C. Bollig, “High-power diode-pumped Tm:YLF slab laser,” Appl. Phys. B 94(2), 195–198 (2009). [CrossRef]

6.

C. T. Wu, Y. L. Ju, Z. G. Wang, Q. Wang, C. W. Song, and Y. Z. Wang, “Diode-pumped single frequency Tm:YAG laser at room temperature,” Laser Phys. Lett. 5(11), 793–796 (2008). [CrossRef]

7.

A. Sato, K. Asai, and T. Itabe, “Double-pass-pumped Tm:YAG laser with a simple cavity configuration,” Appl. Opt. 37(27), 6395–6400 (1998). [CrossRef] [PubMed]

8.

O. A. Buryy, D. Y. Sugak, S. B. Ubizskii, I. I. Izhnin, M. M. Vakiv, and I. M. Solskii, “The comparative analysis and optimization of the free-running Tm3+:YAP and Tm3+:YAG microlasers,” Appl. Phys. B 88(3), 433–442 (2007). [CrossRef]

9.

Y. L. Ju, Q. Wang, C. T. Wu, Z. G. Wang, and Y. Z. Wang, “Lasing Characteristics of a Single-Frequency Tm:YAG Laser,” Laser Phys. 19(6), 1216–1219 (2009). [CrossRef]

10.

W. Koechner, Solid-State Laser Engineering, 6th Revised and Updated Edition (Springer, 2006), Chap. 8.

11.

M. Eichhorn, “Quasi-three-level solid-state lasers in the near and mid infrared based on trivalent rare earth ions,” Appl. Phys. B 93(2-3), 269–316 (2008). [CrossRef]

12.

E. C. Honea, R. J. Beach, S. B. Sutton, J. A. Speth, S. C. Mitchell, J. A. Skidmore, M. A. Emanuel, and S. A. Payne, “115-W Tm:YAG Diode-Pumped Solid-State Laser,” IEEE J. Quantum Electron. 33(9), 1592–1600 (1997). [CrossRef]

13.

K. S. Lai, W. J. Xie, R. F. Wu, Y. L. Lim, E. Lau, L. Chia, and P. B. Phua, “A 150 W 2-micron diode-pumped Tm:YAG laser,” in Conference on Advanced Solid-state Lasers, (Optical Society of America, 2002), Vol. 68, 535–539.

14.

D. Cao, Q. Peng, S. Du, J. Xu, Y. Guo, J. Yang, Y. Bo, J. Zhang, D. Cui, and Z. Xu, “A 200W diode-side-pumped CW 2 μm Tm:YAG laser with water cooling at 8°C,” Appl. Phys. B 103(1), 83–88 (2011). [CrossRef]

15.

D. Cao, S. Du, Q. Peng, J. Xu, Y. Bo, Y. Guo, J. Zhang, D. F. Cui, and Z. Y. Xu, “171.4 W Diode-Side-Pumped Q-Switched 2µm Tm:YAG Laser with a 10 kHz Repetition Rate,” Chin. Phys. Lett. 29(4), 044210 (2012). [CrossRef]

16.

R. C. Stoneman and L. Esterowitz, “Efficient, broadly tunable, laser-pumped Tm:YAG and Tm:YSGG cw lasers,” Opt. Lett. 15(9), 486–488 (1990). [CrossRef] [PubMed]

17.

S. W. Henderson, P. J. M. Suni, C. P. Hale, S. M. Hannon, J. R. Magee, D. L. Bruns, and E. H. Yuen, “Coherent laser radar at 2 µm using solid-state lasers,” IEEE Trans. Geosci. Rem. Sens. 31(1), 4–15 (1993). [CrossRef]

18.

V. Petrov, Y. Tanaka, and T. Suzuki, “Parametric Generation of 1-ps Pulses Between 5 and 11 µm with a ZnGeP2 Crystal,” IEEE J. Quantum Electron. 33(10), 1749–1755 (1997). [CrossRef]

19.

J. Kong, D. Y. Tang, J. Lu, and K. Ueda, “Random-wavelength solid-state laser,” Opt. Lett. 29(1), 65–67 (2004). [CrossRef] [PubMed]

20.

H. H. Yu, Z. B. Pan, H. J. Zhang, Z. Wang, J. Wang, and M. Jiang, “Efficient Tm:LuVO₄ laser at 1.9 μm,” Opt. Lett. 36(13), 2402–2404 (2011). [CrossRef] [PubMed]

OCIS Codes
(140.3480) Lasers and laser optics : Lasers, diode-pumped
(140.3580) Lasers and laser optics : Lasers, solid-state

ToC Category:
Lasers and Laser Optics

History
Original Manuscript: January 2, 2013
Revised Manuscript: February 16, 2013
Manuscript Accepted: February 23, 2013
Published: March 14, 2013

Citation
Caili Wang, Shifeng Du, Yanxiong Niu, Zhichao Wang, Chao Zhang, Qi Bian, Chuan Guo, Jialin Xu, Yong Bo, Qinjun Peng, Dafu Cui, Jingyuan Zhang, Wenqiang Lei, and Zuyan Xu, "Wavelength switchable high-power diode-side-pumped rod Tm:YAG Laser around 2µm," Opt. Express 21, 7156-7161 (2013)
http://www.opticsinfobase.org/oe/abstract.cfm?URI=oe-21-6-7156


Sort:  Author  |  Year  |  Journal  |  Reset  

References

  1. J. Yu, B. C. Trieu, E. A. Modlin, U. N. Singh, M. J. Kavaya, S. Chen, Y. Bai, P. J. Petzar, and M. Petros, “1 J/pulse Q-switched 2 μm solid-state laser,” Opt. Lett.31(4), 462–464 (2006). [CrossRef] [PubMed]
  2. P. J. M. Suni and S. W. Henderson, “1-mJ/pulse Tm:YAG laser pumped by a 3-W diode laser,” Opt. Lett.16(11), 817–819 (1991). [CrossRef] [PubMed]
  3. T. Yokozawa and H. Hara, “Laser-diode end-pumped Tm(3+):YAG eye-safe laser,” Appl. Opt.35(9), 1424–1426 (1996). [CrossRef] [PubMed]
  4. L. J. Lia, B. Q. Yao, Y. L. Ju, and Y. Z. Wang, “8.30 μm Singly Resonant ZnGeP2 Optical Parametric Oscillators Pumped by a Tm,Ho:GdVO4 Laser,” Laser Phys.19(10), 1957–1959 (2009). [CrossRef]
  5. M. Schellhorn, S. Ngcobo, and C. Bollig, “High-power diode-pumped Tm:YLF slab laser,” Appl. Phys. B94(2), 195–198 (2009). [CrossRef]
  6. C. T. Wu, Y. L. Ju, Z. G. Wang, Q. Wang, C. W. Song, and Y. Z. Wang, “Diode-pumped single frequency Tm:YAG laser at room temperature,” Laser Phys. Lett.5(11), 793–796 (2008). [CrossRef]
  7. A. Sato, K. Asai, and T. Itabe, “Double-pass-pumped Tm:YAG laser with a simple cavity configuration,” Appl. Opt.37(27), 6395–6400 (1998). [CrossRef] [PubMed]
  8. O. A. Buryy, D. Y. Sugak, S. B. Ubizskii, I. I. Izhnin, M. M. Vakiv, and I. M. Solskii, “The comparative analysis and optimization of the free-running Tm3+:YAP and Tm3+:YAG microlasers,” Appl. Phys. B88(3), 433–442 (2007). [CrossRef]
  9. Y. L. Ju, Q. Wang, C. T. Wu, Z. G. Wang, and Y. Z. Wang, “Lasing Characteristics of a Single-Frequency Tm:YAG Laser,” Laser Phys.19(6), 1216–1219 (2009). [CrossRef]
  10. W. Koechner, Solid-State Laser Engineering, 6th Revised and Updated Edition (Springer, 2006), Chap. 8.
  11. M. Eichhorn, “Quasi-three-level solid-state lasers in the near and mid infrared based on trivalent rare earth ions,” Appl. Phys. B93(2-3), 269–316 (2008). [CrossRef]
  12. E. C. Honea, R. J. Beach, S. B. Sutton, J. A. Speth, S. C. Mitchell, J. A. Skidmore, M. A. Emanuel, and S. A. Payne, “115-W Tm:YAG Diode-Pumped Solid-State Laser,” IEEE J. Quantum Electron.33(9), 1592–1600 (1997). [CrossRef]
  13. K. S. Lai, W. J. Xie, R. F. Wu, Y. L. Lim, E. Lau, L. Chia, and P. B. Phua, “A 150 W 2-micron diode-pumped Tm:YAG laser,” in Conference on Advanced Solid-state Lasers, (Optical Society of America, 2002), Vol. 68, 535–539.
  14. D. Cao, Q. Peng, S. Du, J. Xu, Y. Guo, J. Yang, Y. Bo, J. Zhang, D. Cui, and Z. Xu, “A 200W diode-side-pumped CW 2 μm Tm:YAG laser with water cooling at 8°C,” Appl. Phys. B103(1), 83–88 (2011). [CrossRef]
  15. D. Cao, S. Du, Q. Peng, J. Xu, Y. Bo, Y. Guo, J. Zhang, D. F. Cui, and Z. Y. Xu, “171.4 W Diode-Side-Pumped Q-Switched 2µm Tm:YAG Laser with a 10 kHz Repetition Rate,” Chin. Phys. Lett.29(4), 044210 (2012). [CrossRef]
  16. R. C. Stoneman and L. Esterowitz, “Efficient, broadly tunable, laser-pumped Tm:YAG and Tm:YSGG cw lasers,” Opt. Lett.15(9), 486–488 (1990). [CrossRef] [PubMed]
  17. S. W. Henderson, P. J. M. Suni, C. P. Hale, S. M. Hannon, J. R. Magee, D. L. Bruns, and E. H. Yuen, “Coherent laser radar at 2 µm using solid-state lasers,” IEEE Trans. Geosci. Rem. Sens.31(1), 4–15 (1993). [CrossRef]
  18. V. Petrov, Y. Tanaka, and T. Suzuki, “Parametric Generation of 1-ps Pulses Between 5 and 11 µm with a ZnGeP2 Crystal,” IEEE J. Quantum Electron.33(10), 1749–1755 (1997). [CrossRef]
  19. J. Kong, D. Y. Tang, J. Lu, and K. Ueda, “Random-wavelength solid-state laser,” Opt. Lett.29(1), 65–67 (2004). [CrossRef] [PubMed]
  20. H. H. Yu, Z. B. Pan, H. J. Zhang, Z. Wang, J. Wang, and M. Jiang, “Efficient Tm:LuVO₄ laser at 1.9 μm,” Opt. Lett.36(13), 2402–2404 (2011). [CrossRef] [PubMed]

Cited By

Alert me when this paper is cited

OSA is able to provide readers links to articles that cite this paper by participating in CrossRef's Cited-By Linking service. CrossRef includes content from more than 3000 publishers and societies. In addition to listing OSA journal articles that cite this paper, citing articles from other participating publishers will also be listed.


« Previous Article  |  Next Article »

OSA is a member of CrossRef.

CrossCheck Deposited