Laser & Optoelectronics Progress, Volume. 60, Issue 21, 2119001(2023)
Second Harmonic Characteristics of Three Crystals Based on Quantum Impedance Lorentz Oscillator
References(28)
[1] Kurtz S K, Perry T T. A powder technique for the evaluation of nonlinear optical materials[J]. Journal of Applied Physics, 39, 3798-3813(1968).
[2] Wang Q B, Zhou W J, Dong W M et al. Rb21.89W32.66O108: an excellent mid-and far-IR nonlinear-optical material with a wide band gap[J]. Inorganic Chemistry, 59, 4601-4607(2020).
[3] Wu Q, Zhou J F, Liu X M et al. Ca3(TeO3)2(MO4) (M=Mo, W): mid-infrared nonlinear optical tellurates with ultrawide transparency ranges and superhigh laser-induced damage thresholds[J]. Inorganic Chemistry, 60, 18512-18520(2021).
[4] Kulkarni R B, Anis M, Hussaini S S et al. Tuning optical properties of cadmium thiourea acetate nonlinear optical crystal exploiting organic ligand of L-proline[J]. Modern Physics Letters B, 33, 1850424(2019).
[5] Jerphagnon J, Kurtz S K. Maker fringes: a detailed comparison of theory and experiment for isotropic and uniaxial crystals[J]. Journal of Applied Physics, 41, 1667-1681(1970).
[6] Vivek P, Suvitha A, Jauhar R M et al. Determination of SHG deff by Maker fringes studies on unidirectional grown guanidinium chlorochromate single crystal for NLO device applications[J]. Journal of Optics, 50, 77-82(2021).
[7] Nash F R, Bergman J G, Boyd G D et al. Optical nonlinearities in LiIO3[J]. Journal of Applied Physics, 40, 5201-5206(1969).
[8] Wu G X, Chen J H, Li D R et al. Quasi-phase-matching method based on coupling compensation for surface second-harmonic generation in optical fiber nanowire coupler[J]. ACS Photonics, 5, 3916-3922(2018).
[9] Cazan R, Geppert C, Nörtershäuser W et al. Towards sympathetic cooling of trapped ions with laser-cooled Mg+ ions for mass spectrometry and laser spectroscopy[J]. Hyperfine Interactions, 196, 177-189(2010).
[10] Zhang G H, Xu D, Lü M K et al. Violet laser output based on frequency doubling of diode laser using ZCTC crystal[J]. Acta Optica Sinica, 21, 305-308(2001).
[11] Nie H K, Ning J, Zhang B T et al. Recent progress of optical-superlattice-based mid-infrared optical parametric oscillators[J]. Chinese Journal of Lasers, 48, 0501008(2021).
[12] Niu N, Qu D P, Dou W et al. 348.9 nm intra-cavity frequency-doubling ultraviolet laser in blue laser diode pumped Pr∶YLF crystal[J]. Chinese Journal of Lasers, 45, 1201003(2018).
[13] Otaguro W S, Wiener-Avnear E, Porto S P S. Determination of the second-harmonic-generation coefficient and the linear electro-optic coefficient in LiIO3 through oblique Raman phonon measurements[J]. Applied Physics Letters, 18, 499-501(1971).
[14] Triyono D, Purnamasari I, Rafsanjani R A. Effect of the Zr-substitution on the structural and electrical properties of LaFeO3∶XRD, Raman scattering, SEM, and impedance spectroscopy study[J]. Crystals, 10, 399(2020).
[15] Zhao Z G, Xuan H W, Wang J C et al. Research progresses on vacuum-ultraviolet 193 nm band solid-state lasers[J]. Acta Optica Sinica, 42, 1134010(2022).
[16] Shen J, Wei B, Zhou J et al. First-principle study of electronic structure and optical properties of Ba(Mg1/3Nb2/3)O3[J]. Acta Physica Sinica, 64, 217801(2015).
[17] Cui H W, Zhang F C, Shao T T. First-principles study on electronic structure and optical properties of Sn-doped ZnO[J]. Acta Optica Sinica, 36, 0716002(2016).
[18] Caputo R, Demir S, Tekin A. First-principles crystal structure prediction of Cu(I)-TCNQ polymorphs[J]. The Journal of Physical Chemistry C, 124, 70-82(2020).
[19] Aversa C, Sipe J E. Nonlinear optical susceptibilities of semiconductors: results with a length-gauge analysis[J]. Physical Review B, 52, 14636-14645(1995).
[20] Chen C T, Yao W J. Discovery of KBBF family crystals and capability of deep-ultraviolet harmonic generation[J]. Acta Optica Sinica, 31, 0900108(2011).
[21] Lin Z S, Wu Y C. Development of theoretical methods for nonlinear optical crystals exploration[J]. Journal of Synthetic Crystals, 48, 1773-1781(2019).
[22] Liang F, Lin Z S, Wu Y C. First principle study of nonlinear optical crystals[J]. Acta Physica Sinica, 67, 114203(2018).
[23] Zhou G G, Lu G W, Yu Y H et al. Calculation for linear and nonlinear optical properties of LBO crystals[J]. Chinese Journal of Lasers, 37, 1342-1346(2010).
[24] Zhu J H, Zhang J, Li Y et al. Quantized impedance dealing with the damping behavior of the one-dimensional oscillator[J]. AIP Advances, 5, 117217(2015).
[25] Zhang J, Li K, Fang Z J et al. Quantum impedance Lorentz oscillator and its 1- and 2-photon-absorption applications[J]. AIP Advances, 11, 075218(2021).
[26] Li Y J. Study on new second-order nonlinear optical crystal materials[D], 68-121(2011).
[27] Romeu M C, Oliveira R G M, Sales A J M et al. Impedance spectroscopy study of TiO2 addition on the ceramic matrix Na2Nb4O11[J]. Journal of Materials Science: Materials in Electronics, 24, 4993-4999(2013).
[28] Feng X, Zhang Z W. Broadband mid-infrared light based on difference frequency generators[J]. Chinese Journal of Lasers, 49, 0101018(2022).
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Qiqi Bai, Kai Li, Xiaofeng Wang, Yu Yu, Yulei Wang, Yong Zhang, Peide Zhao, Yuanqin Xia. Second Harmonic Characteristics of Three Crystals Based on Quantum Impedance Lorentz Oscillator[J]. Laser & Optoelectronics Progress, 2023, 60(21): 2119001
Paper Information
Category: Nonlinear Optics
Received: Sep. 19, 2022
Accepted: Oct. 27, 2022
Published Online: Nov. 16, 2023
The Author Email: Yong Zhang (13902109749@163.com), Peide Zhao (pdzhao@hebut.edu.cn), Yuanqin Xia (xiayq@hebut.edu.cn)
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