Tb:LiYF4单晶生长及光谱性能研究

doi:10.15541/jim20260023

摘要/Abstract

摘要： LiYF₄晶体是一种具有优异光学和物理性能的激光基质材料,Tb³⁺掺杂使其在绿、黄光波段高能量脉冲激光领域具有重要应用潜力。然而氟化物原料易潮解、高温下组分易挥发以及强腐蚀性等问题,对高品质晶体制备及生长成本控制带来了挑战。本研究采用真空密封铂金坩埚工艺结合垂直布里奇曼法成功生长了尺寸为ϕ16 mm×120 mm的Tb:LiYF₄单晶。通过多种测试手段对晶体的结晶质量、组分均匀性及光学性能进行了系统表征。晶体在透明波段内透过率超过93%,吸收系数低于0.02 cm^-1,具有优异的光学质量。基于Judd-Ofelt理论,计算得到三个振子强度参数以及一系列光谱参数,并测试了变温条件下荧光发射光谱以及荧光衰减曲线。Tb:LiYF₄在544 nm和585 nm处表现出强荧光发射,荧光分支比分别为57%和15%,常温下⁵D₄能级荧光寿命为4.87 ms,较大的荧光分支比以及较长的荧光寿命表明Tb:LiYF₄晶体具有在绿光与黄光波段实现高效率激光输出的潜力。本研究成功建立了一种可行的Tb:LiYF₄晶体生长方法,并对其光谱性能进行了系统性研究,为构建高效率绿、黄光固体激光器提供了材料基础与实验依据。

关键词: 布里奇曼法, 坩埚密封, Tb:LiYF₄晶体, Judd-Ofelt理论, 光谱性能

Abstract: LiYF₄ crystal is a laser host material with excellent optical and physical properties, and Tb³⁺ doping endows it with great potential for high-energy pulsed laser operation in the green and yellow spectral regions. However, the hygroscopicity of fluoride raw materials, the volatility of components at high temperatures, and the strong corrosiveness pose challenges to the growth of high-quality crystals and cost control. In this work, a Tb:LiYF₄ single crystal with dimensions of ϕ16 mm × 120 mm was successfully grown using a vacuum-sealed platinum crucible combined with the vertical Bridgman method. The crystalline quality, compositional uniformity, and optical properties were systematically characterized using multiple techniques. The crystal exhibits a transmittance exceeding 93% and an absorption coefficient below 0.02 cm^-1 in the transparent region, indicating excellent optical quality. Based on Judd-Ofelt theory, three intensity parameters and related spectroscopic parameters were obtained, and temperature dependent fluorescence emission spectra and fluorescence decay curves were measured. Strong emissions were observed at 544 nm and 585 nm, with fluorescence branching ratios of 57% and 15%, respectively. The fluorescence lifetime of the ⁵D₄ level at room temperature is 4.87 ms. The relatively large branching ratios and the long fluorescence lifetime indicate that Tb:LiYF₄ crystal has great potential for achieving efficient laser output in the green and yellow spectral regions. This work establishes a feasible growth method for Tb:LiYF₄ crystals and provides a systematic investigation of their spectroscopic properties, providing a material basis and experimental support for the development of high-efficiency green and yellow solid-state lasers.

Key words: Bridgman method, sealed crucible, Tb:LiYF₄ crystal, Judd-Ofelt theory, spectroscopic properties

中图分类号:

余学舟, 刘国晋, 黄昌保, 李亚, 陈伟豪, 祁华贝, 倪友保, 吴海信. Tb:LiYF₄单晶生长及光谱性能研究[J]. 无机材料学报, DOI: 10.15541/jim20260023.

YU Xuezhou, LIU Guojin, HUANG Changbao, LI Ya, CHEN Weihao, QI Huabei, Ni Youbao, WU Haixin. Investigation of Crystal Growth and Spectroscopic Properties of Tb:LiYF₄ Single Crystals[J]. Journal of Inorganic Materials, DOI: 10.15541/jim20260023.

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Tb:LiYF₄单晶生长及光谱性能研究

Investigation of Crystal Growth and Spectroscopic Properties of Tb:LiYF₄ Single Crystals

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