[1] . Modeling of Thermal Lensing and Higher Order Ring Mode Oscillation in End-pumped CW Nd:YAG Lasers[J]. IEEE Quantum Electron, 1992, 28: 1046-1056.

[2] COUSINS A K. Temperature and Thermal Stress Scaling in Finite-length End-pumped Laser Rods [ J].IEEE Quantum Electron,1992,28: 1057-1069.

[3] . Analysis of Laser Beam Quality Degradation Caused by Quartic Phase Aberrations[J]. Appl Opt, 1993, 32: 5894-5902.

[4] . Power Scaling of Diode-pumped Nd:YVO4Lasers[J]. IEEE Quantum Electron, 2002, 38: 1291-1300.

[5] . Design Criteria for Concentration Optimization in Scaling Diode End-pumped Lasers to High powers: Influence of Thermal Fracture[J]. IEEE Quantum Electron, 1999, 35: 234-239.

[6] . Low-noise 62W CW intracavity-doubled TEM00Nd:YVO4green laser pumped at 888 nm[J]. Opt Lett, 2007, 32: 802-804.

[7] KOECHNER W. Solid-state Laser Engineering [M]. Beijing: Science Press. 2002.

[8] . High Average Power Laser Diode Pumped Solid-state Laser[J]. Chinese J Lasers, 2009, 36: 1605-1618.

[9] . Highly Efficient Nd: YVO4Laser by Direct in-band Diode Pumping at 914 nm[J]. Opt Lett, 2009, 34: 2159-2161.

[10] . High-efficiency 60W TEM00Nd:YVO4Oscillator Pumped at 888 nm[J]. Opt Lett, 2006, 31: 3297-3299.

[11] . Laser Operation with Near Quantum-defect Slope Efficiency in Nd: YVO4Under Direct Pumping Into the Emitting Level[J]. Appl Phys Lett, 2003, 82: 844-846.

[12] . Efficient Laser Emission in Concentrated Nd Laser Materials Under Pumping Into the Emitting Level[J]. Quan Electron Lett, 2002, 38: 240-245.

[13] . Laser Operation of LD End-pumped Grown-together Nd: YVO4/ YVO4Composite Crystal[J]. Laser Phys Lett, 2008, 5: 429-432.

[14] PAVEL N, LUPEI V. High-power Continuous-wave Nd Lasers Under Diode Pumping Directly Into the 4F3/2 Emitting Level [J].Proc of SPIE,7007: 700705.

[15] . Theoretical Investigation of Feasibility of Yb: YAG as Laser Material for Nanosecond Pulse Emission with Large Energies in the Joule Range[J]. Opt Commun, 2007, 274: 422-428.

[16] . Crystal Growth and Spectral Properties of Yb3Al5O12[J]. Journal of Crystal Crowth, 2003, 257: 272-275.

[17] . 8. 9W Continuous-wave, Diode-end-pumped All-solid-state Nd: YVO4 laser Operating at 914 nm[J]. Laser Phys, 2009, 19: 389-391.

[18] . Development of a High-energy, Quasi-three-level Nd:YVO4Laser at 914 nm for Deep-blue Light Generation[J]. Proc SPIE, 2008, 7153: 715316.

[19] . 2W Diode-end-pumped Nd:YAG Laser Operating at 946 nm[J]. Opt Lett, 2006, 31: 1869-1871.

[20] . 3.8W of Cw Blue Light Generated by Intracavity Frequency Doubling of a 946 nm Nd:YAG laser with LBO[J]. Appl Phys B, 2006, 83: 241-243.

[21] PHELAN R J, CONCORD J, REDIKER R H,et al.Optically Pumped Semiconductor Laser [P] US Patent. Patent no. 3568087.

[22] . Optical Pumping ofⅣ-ⅥSemiconductor Multiple Quantum Well Materials Using a GaSB-based Laser with Emission atλ=2.5μm[J]. J Appl Phys, 2005, 97: 053103.

[23] . Optically Pumped Blue Organic Semiconductor Lasers[J]. Appl Phys Lett, 1998, 72: 144-146.

[24] KARNUTSCH C, LINDER N, LUFT J,et al.Semiconductor Optical Pumping Device for Radiation Emission and the Production Method Thereof [P]. US Patent. Patent no.7529284 B2.

[25] http://www.coherent.com.cn/.

[26] . High-power Diode-bar-pumped Intracavity-frequency-doubled Nd:YLF Laser[J]. Opt Commun, 1998, 156: 49-52.

[27] . Power Scaling of Diode-pumped Nd: :YVO4Lasers[J]. IEEE Quantum Electron, 2002, 38: 1291-1299.

[28] CHENG E, DUDLEY D R, NIGHAN W L,et al.Laser with Low Doped Gain Medium [P]. US. Patent, Patent No. US6185235. 2001.

[29] . Power Scaling of End-Pumped Solid-State Rod Lasersby Longitudinal Dopant Concentration Gradients[J]. IEEE Quantum Electron, 2008, 44: 232-244.

[30] 郑耀辉,王雅君,彭堃墀,等.端面泵浦的高功率激光器[P].中国发明专利,申请号:ZL200910083540.3.

[31] MENDE J, SCHMID E, SPEISER J. Thin Disk Laser: Power Scaling to the kW Regime in Fundamental Mode Operation [C]//Proc SPIE, 27 February 2009.

[32] . Axial Mode Tuning of a Single Frequency Yb:YAG Thin Disk Laser[J]. Appl Phys B, 2005, 81: 1091-1096.

[33] . Surface Loss Limit of the Power Scaling of a Thin-disk Laser[J]. J Opt Soc Am B, 2006, 23: 1074-1082.

[34] . Thermal Modelling of Continuous-wave End-pumped Solid-state Lasers[J]. Appl Phys Lett, 1990, 56: 1831-1833.

[35] . Influence of Pump Beam Size on Laser Diode End-pumped Solid State Lasers[J]. Optics&Laser Technology, 1999, 31: 555-558.

[36] . A Twisted-Mode Technique for Obtaining Axially Uniform Energy Density in a Laser Cavity[J]. Appl Opt, 1965, 4: 142-143.

[37] . Single-frequency Microchip Nd lasers[J]. Opt Lett, 1989, 14: 24-26.

[38] . Large-amplitude Fluctuations Due to Longitudinal Mode Coupling in Diode-pumped Intracavity-doubled Nd:YAG Lasers[J]. J Opt Soc Am B, 1986, 3: 1175-1180.

[39] . 1. 12W Single-frequency Green Laser Adopting Birefringent Filter Technique[J]. Acta Phot Sini, 2005, 34: 321-324.

[40] . Four watt Long-term Stable Intracavity Frequency-doubling Nd:YVO4 Laser of Single-frequency Operation Pumped by a Fiber-coupled Laser Diode[J]. Appl Opt, 2007, 46: 5336-5339.

[41] . All-solid-state High-efficiency High-power Nd: YVO4/KTP Laser of Single-frequency Operation[J]. Chinese J Lasers, 2007, 34: 739-743.

[42] LU B D. Laser optics [M]. the third edition. Higher Education Press. 2003.

[43] . CW Second Harmonic Generation with Elliptical Gaussian Beams[J]. Opt Commun, 1996, 123: 207-214.

[44] . General Analysis of typeⅠSecond-harmonic Generation with Elliptical Gaussian Beams[J]. J Opt Soc Am B, 1997, 14: 2010-2016.

[45] . Self-suppression of Axial Mode Hopping by Intracavity Second-harmonic Generation[J]. Opt Lett, 1997, 22: 375-377.

[46] . Progress of All-solid-state Single-frequency Lasers[J]. Chinese J Lasers, 2009, 36: 1635-1642.

[47] . The Influence of Nonlinear Spectral Bandwidth on Single Longitudinal Mode Intracavity Second Harmonic Generation[J]. Opt Commun, 2005, 248: 241-248.

[48] . Low-noise Diode-pumped Intracavity Doubled Laser with Off-axially Cut Nd:YVO4[J]. Opt Lett, 1994, 19: 1624-1625.

[49] 张宽收,郑耀辉,彭堃墀.单频内腔倍频激光器[P].中国发明专利,申请号:ZL200810079204.3.

[50] . High-stabiliby Single-frequency Green Laser with a Wedge Nd: YVO4as a Polarizing Beam Splitter[J]. Opt Commun, 2010, 283: 309-312.