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Phase transition properties of the LIPSS induced by femtosecond laser direct writing on PMN-PT crystal
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摘要:
本文提出一种由飞秒激光直写技术诱导的基于弛豫铁电体PMN-PT晶体的表面周期结构(LIPSS),通过不同激光参数的改变,实现了LIPSS结构周期从750 nm到3 μm的变化。最后,通过升高温度探究了LIPSS结构的相变特性。对比基底的相变特性,飞秒激光诱导的LIPSS结构的居里温度有明显的降低,这一特性将会为基于PMN-PT晶体的温控调制器的制备提供新思路。
Abstract:In this paper, we propose a femtosecond laser-induced surface periodic structure (LIPSS) based on relaxed ferroelectric PMN-PT crystals. By changing the applied laser parameters, the period of the LIPSS structure is varied from 750 nm to 3 μm. Finally, the phase transition properties of the LIPSS structure are investigated by increasing the temperature. Compared to the phase transition properties of the substrate, the Curie temperature of the LIPSS structure is significantly reduced, and this will provide a possible new idea for the preparation of temperature-controlled modulators based on PMN-PT crystals.
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Key words:
- femtosecond laser direct writing /
- LIPSS /
- PMN-PT crystal /
- phase transition
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图 1 飞秒激光加工示意图。(a) 飞秒激光直写PMN-PT晶体LIPSS结构示意图,红色箭头代表激光扫描的方向,蓝色箭头代表激光的偏振方向;(b)飞秒激光诱导LIPSS结构原理图
Figure 1. Schematic diagram of femtosecond laser processing. (a) Schematic diagram of LIPSS in the PMN-PT crystal by femtosecond laser direct writing, the red arrow represents the direction of laser scanning, the blue arrow represents the direction of polarization of the laser; (b) Schematic diagram of the femtosecond laser-induced LIPSS
图 2 飞秒激光诱导的SWPSS结构的表面形貌。 (a)~(c) 速度分别为5 mm/s、3 mm/s和2 mm/s时的SWPSS结构
Figure 2. Morphology of SWPSS induced by femtosecond laser. (a)~(c) SWPSS at velocities of 5 mm/s, 3 mm/s, and 2 mm/s respectively
图 3 (a) 速度为0.7 mm/s、0.8 mm/s和0.9 mm/s的LSFL表面形貌;(b) LIPSS结构周期与激光参数的关系
Figure 3. (a) Morphology of the LSFL with velocities of 0.7 mm/s, 0.8 mm/s, and 0.9 mm/s respectively; (b) Period of LIPSS in relation to laser parameters
图 4 (a) LIPSS结构随温度变化的拉曼曲线变化图,插图为拉曼位移为50 cm−1位置附近的拉曼曲线变化图;(b) PMN-PT晶体随温度变化的拉曼信号强度变化图;(c) LIPSS结构随温度变化的拉曼信号强度变化图
Figure 4. (a) Raman spectra of the LIPSS with the variation of temperature, the inset shows the variation of the Raman spectra at the Raman shift near the 50 cm−1 ; (b) Intensity of Raman signal of the PMN-PT crystal with the variation of temperature; (c) Intensity of Raman signal of the LIPSS with the variation of temperature
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[1] Jia Y C, Wang S X, Chen F. Femtosecond laser direct writing of flexibly configured waveguide geometries in optical crystals: fabrication and application[J]. Opto-Electron Adv, 2020, 3(10): 190042. doi: 10.29026/oea.2020.190042
[2] Li L Q, Kong W J, Chen F. Femtosecond laser-inscribed optical waveguides in dielectric crystals: a concise review and recent advances[J]. Adv Photonics, 2022, 4(2): 024002. doi: 10.1117/1.AP.4.2.024002
[3] Li L Q, Li Z Q, Nie W J, et al. Femtosecond-laser-written S-curved waveguide in Nd: YAP crystal: fabrication and multi-gigahertz lasing[J]. J Light Technol, 2020, 38(24): 6845−6852. doi: 10.1109/JLT.2020.3015690
[4] Tan D Z, Sun X Y, Li Z L, et al. Effectively writing low propagation and bend loss waveguides in the silica glass by using a femtosecond laser[J]. Opt Lett, 2022, 47(18): 4766−4769. doi: 10.1364/OL.470670
[5] Yang Q X, Liu H L, He S, et al. Circular cladding waveguides in Pr: YAG fabricated by femtosecond laser inscription: Raman, luminescence properties and guiding performance[J]. Opto-Electron Adv, 2021, 4(2): 200005. doi: 10.29026/oea.2021.200005
[6] Xu X Y, Wang T X, Chen P C, et al. Femtosecond laser writing of lithium niobate ferroelectric nanodomains[J]. Nature, 2022, 609(7927): 496−501. doi: 10.1038/s41586-022-05042-z
[7] Wu P F, Jiang X R, Zhang B, et al. Mode-controllable waveguide fabricated by laser-induced phase transition in KTN[J]. Opt Express, 2020, 28(17): 25633−25641. doi: 10.1364/OE.401407
[8] Zhang Q, Li M, Xu J, et al. Reconfigurable directional coupler in lithium niobate crystal fabricated by three-dimensional femtosecond laser focal field engineering[J]. Photonics Res, 2019, 7(5): 503−507. doi: 10.1364/PRJ.7.000503
[9] Lv H Y, Chu L R, Wang S X, et al. Layer-dependent nonlinear optical properties of two-dimensional InSe and its applications in waveguide lasers[J]. Opt Express, 2022, 30(13): 23986−23999. doi: 10.1364/OE.462811
[10] Xin C, Yang L, Li J W, et al. Conical hollow microhelices with superior swimming capabilities for targeted cargo delivery[J]. Adv Mater, 2019, 31(25): 1808226. doi: 10.1002/adma.201808226
[11] Chen W L, Yan Z, Tian J, et al. Flexible four-dimensional optical data storage enabled by single-pulse femtosecond laser irradiation in thermoplastic polyurethane[J]. Opt Lett, 2021, 46(13): 3211−3214. doi: 10.1364/OL.432092
[12] Lei Y H, Sakakura M, Wang L, et al. High speed ultrafast laser anisotropic nanostructuring by energy deposition control via near-field enhancement[J]. Optica, 2021, 8(11): 1365−1371. doi: 10.1364/OPTICA.433765
[13] Birnbaum M. Semiconductor surface damage produced by ruby lasers[J]. J Appl Phys, 1965, 36(11): 3688−3689. doi: 10.1063/1.1703071
[14] Li Y N, Wu Q, Yang M, et al. Uniform deep-subwavelength ripples produced on temperature controlled LiNbO3: Fe crystal surface via femtosecond laser ablation[J]. Appl Surf Sci, 2019, 478: 779−783. doi: 10.1016/j.apsusc.2019.02.037.
[15] Zhang D S, Li X Z, Fu Y, et al. Liquid vortexes and flows induced by femtosecond laser ablation in liquid governing formation of circular and crisscross LIPSS[J]. Opto-Electron Adv, 2022, 5(2): 210066. doi: 10.29026/oea.2022.210066
[16] Zhang Y C, Jiang Q L, Long M Q, et al. Femtosecond laser-induced periodic structures: mechanisms, techniques, and applications[J]. Opto-Electron Sci, 2022, 1(6): 220005. doi: 10.29026/oes.2022.220005
[17] Ren Y Y, Zhang L M, Romero C, et al. Femtosecond laser irradiation on Nd: YAG crystal: surface ablation and high-spatial-frequency nanograting[J]. Appl Surf Sci, 2018, 441: 372−380. doi: 10.1016/j.apsusc.2018.01.217
[18] Huang J, Jiang L, Li X W, et al. Fabrication of highly homogeneous and controllable nanogratings on silicon via chemical etching-assisted femtosecond laser modification[J]. Nanophotonics, 2019, 8(5): 869−878. doi: 10.1515/nanoph-2019-0056
[19] Cho D H, Hong S H, Lee W J, et al. Colorful solar cells utilizing off-axis light diffraction via transparent nanograting structures[J]. Nano Energy, 2021, 80: 105550. doi: 10.1016/j.nanoen.2020.105550
[20] Fang Z, Jiang X D, Tian X, et al. Ultratransparent PMN-PT electro-optic ceramics and its application in optical communication[J]. Adv Opt Mater, 2021, 9(13): 2002139. doi: 10.1002/adom.202002139
[21] Deng C G, Ye L X, He C J, et al. Reporting excellent transverse piezoelectric and electro-optic effects in transparent rhombohedral PMN-PT single crystal by engineered domains[J]. Adv Mater, 2021, 33(43): 2103013. doi: 10.1002/adma.202103013
[22] Li Q, Liu Y B, Liu J F, et al. Enhanced piezoelectric properties and improved property uniformity in Nd-doped PMN-PT relaxor ferroelectric single crystals[J]. Adv Funct Mater, 2022, 32(25): 2201719. doi: 10.1002/adfm.202201719
[23] Piredda G, Stroj S, Ziss D, et al. Micro-machining of PMN-PT crystals with ultrashort laser pulses[J]. Appl Phys A, 2019, 125(3): 201. doi: 10.1007/s00339-019-2460-9
[24] Chen X, Liu D W, Liu S, et al. Optical induction and erasure of ferroelectric domains in tetragonal PMN-38PT crystals[J]. Adv Opt Mater, 2022, 10(4): 2102115. doi: 10.1002/adom.202102115
[25] Shen T L, Si J H, Chen T, et al. Fabrication of microgrooves in PMN-PT using femtosecond laser irradiation and acid etching[J]. Appl Opt, 2022, 61(21): 6234−6240. doi: 10.1364/AO.459556
[26] Sipe J E, Young J F, Preston J S, et al. Laser-induced periodic surface structure. I. Theory[J]. Phys Rev B, 1983, 27(2): 1141−1154. doi: 10.1103/PhysRevB.27.1141
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