Crystal growth and spectral properties of Tb:Lu<sub>2</sub>O<sub>3</sub>

Cite this Article

Shi Jiaojiao, Liu Bin, Wang Qingguo, Tang Huili, Wu Feng, Li Dongzhen, Zhao Hengyu, Wang Zhanshan, Deng Wen, Xu Zian, Xu Jiayue, Xu Xiaodong, Xu Jun. Crystal growth and spectral properties of Tb:Lu₂O₃**

Project supported by the National Natural Science Foundation of China (Grant No. 61621001), the National Key Research and Development Program of China (Grant Nos. 2016YFB1102202 and 2016YFB0701002), and the Fundamental Research Funds for the Central Universities, China. We acknowledge the help of MOE Key Laboratory of Advanced Micro-Structured Materials and School of Physical Science and Technology, Guangxi University.

. Chinese Physics B, 2018, 27(9): 097801 Copy to clipboard

Permissions

Crystal growth and spectral properties of Tb:Lu₂O₃**

Shi Jiaojiao^{1, 2}, Liu Bin^{1, 2}, Wang Qingguo^{1, 2}, Tang Huili^{1, 2, 4}, Wu Feng^{1, 2}, Li Dongzhen³, Zhao Hengyu^{1, 2}, Wang Zhanshan^{1, 2}, Deng Wen⁵, Xu Zian⁶, Xu Jiayue⁶, Xu Xiaodong^{3, †}, Xu Jun^{1, 2, 7, ‡}

1School of Physics Science and Engineering, Institute for Advanced Study, Tongji University, Shanghai 200092, China

2MOE Key Laboratory of Advanced Micro-Structure Materials, Shanghai 201899, China

3Jiangsu Key Laboratory of Advanced Laser Materials and Devices, School of Physics and Electronic Engineering, Jiangsu Normal University, Xuzhou 221116, China

4State Key Laboratory of Crystal Materials, Shandong University, Jinan 250100,China

5School of Physical Science and Technology, Guangxi University, Nanning 530004, China

6Institute of Crystal Growth, School of Materials Science and Engineering, Shanghai Institute of Technology, Shanghai 201418, China

7Shanghai Engineering Research Center for Sapphire Crystals, Shanghai 201899, China

† Corresponding author. E-mail: xdxu79@jsnu.edu.cn

xujun@mail.shcnc.ac.cn

Abstract

The crystal growth, x-ray diffraction pattern, absorption spectrum, emission spectrum, and fluorescence lifetime of a Tb:Lu₂O₃ single crystal were studied. Excited at 483 nm, the peak absorption cross-section was calculated to be 3.5 × 10⁻²² cm₂, and the full width at half maximum was found to be 2.85 nm. The Judd–Ofelt (J–O) intensity parameters Ω₂, Ω₄, and Ω₆ were computed to be 3.79 × 10⁻²⁰ cm², 1.30 × 10⁻²⁰ cm², and 1.08 × 10⁻²⁰ cm², with a spectroscopic quality factor Ω₄/Ω₆ being 1.20. The emission cross-sections of green emission around 543 nm and yellow emission around 584 nm were calculated to be 9.43 × 10⁻²² cm² and 1.32 × 10⁻²² cm², respectively. The fluorescence lifetime τ_exp of ⁵D₄ was fitted to be 1.13 ms. The data suggest that the Tb:Lu₂O₃ crystal could be a potential candidate for green and yellow laser operation.

PACS: 78.55.-m;42.70.Hj;78.47.da

Keyword:fluorescence spectra;laser materials;excited states

Show Figures

1. Introduction

Visible lasers are very attractive for their widespread applications, such as optical storage devices, display technology, medicine, materials processing, and more.^[1,2] Recently, visible lasers have aroused much attention due to the invention of the InGaN laser diode,^[3] because the emission wavelength of InGaN laser diode matches well with the absorption wavelength of most rare-earth ions, which is favorable for laser operation.

Pr³⁺ is a famous rare earth ion in the visible laser operation. Efficient laser operations in deep red, red, orange, green, and blue regions have been demonstrated for Pr³⁺-doped laser materials.^[4] Unfortunately, for Pr³⁺, there is no yellow emission transition. The electronic configuration of trivalent terbium ions is [Xe]4f⁸, with a large energy gap (∼ 15000 cm⁻¹) between the metastable ⁵D₄ excited state and the lower ⁷F_J (J = 6, 5, …, 0) multiplets,^[5], which determines the presence of multiple visible emissions in red, yellow, green, and blue spectral ranges, high luminescence quantum efficiency, and a long lifetime of the emission state (ranging from a few hundred microseconds to a few milliseconds).^[6] Particularly, the yellow emission corresponding to the ⁵D₄ → ⁷F₄ transition makes Tb³⁺ ions a good candidate for yellow laser operation, which is not included by Pr³⁺ ions. Various materials doped with Tb³⁺ ions have been researched for fluorescence imaging and green phosphors.^[7–9] In 1973, the stimulated emission at 544.5 nm was first demonstrated in Tb:LiYF₄ crystals.^[10] Recently, pumped by the InGaN laser diode, high-efficiency room temperature continuous wave lasers emitting green (⁵D₄ → ⁷F₅) and yellow (⁵D₄ → ⁷F₄) light from Tb³⁺-doped fluoride crystals have also been achieved, with the maximum slope efficiencies being 58% around 545 nm in the green region and 20% around 585 nm in the yellow region.^[6,11]

The laser performance of rare-earth ions doped fluoride crystals strongly depends on the temperature. Thus it is necessary to find a new single crystal host, which not only owns the low phonon energy similar with fluoride crystals, but also has better thermal and mechanical properties than fluoride crystals. The sesquioxide Lu₂O₃ belonging to the bixbyite structure with the cubic space group Ia3^[12] meets these requirements well. They possess higher thermal conductivity (∼ 12.5 W/m·K) than that of fluoride materials (e.g., CaF₂ ∼ 7.0 W/m·K).^[13,14] Compared with pure lutecia, the thermal conductivity of 3 at.% Yb³⁺-doped lutecia only decreases slightly to 11.0 W/m·K.^[15] In addition, the phonon energy of Lu₂O₃ (∼ 430 cm⁻¹) is lower than that of other oxides,^[15] which means that the rare earth ions doped into Lu₂O₃ own lower non-radiative transition rates between the metastable electron levels, resulting in higher radiation probability and quantum efficiency. Up to now, the optical characteristics of Tm³⁺, Er³⁺, and Yb³⁺ doped Lu₂O₃ crystals^[16,17] have been reported. However, very few researches were focused on the Lu₂O₃ crystals doped with Tb³⁺ ions.

In this work, we study the x-ray diffraction (XRD) pattern, absorption spectrum, Judd–Ofelt (J–O) theory, emission spectrum, and fluorescence lifetime of a Tb:Lu₂O₃ crystal grown by floating zone (Fz) method in detail.

2. Experiments

2.1. Crystal growth

The Lu₂O₃ doped with trivalent terbium ions was grown by the Fz method. The Lu₂O₃ (4N purity) and Tb₄O₇ (4N purity) powders were used as raw materials and weighed precisely according to the equation (Tb_xLu_1−x)₂O₃ (x = 0.01). After mixed evenly in an agate mortar, the raw powders were pressed into two rods and then sintered in the air at 1780 °C for 24 h. The rotation rate and growth rate were selected to be 8–10 rpm and 1–2 mm/h, respectively. High-purity argon gas was aerated into the floating zone furnace as a protective atmosphere. The grown Tb:Lu₂O₃ was slowly cooled to room temperature. There was an internal stress in the crystal due to the large temperature gradient in the growth process of the Fz method. Therefore, the grown Tb:Lu₂O₃ crystal was annealed in air at 1700 °C for 24 h to eliminate the internal stress. Then the obtained Tb:Lu₂O₃ crystal was cut into 2.5 mm × 4 mm × 1 mm and polished for spectral measurements.

2.2. Spectral measurements

The following measurements were performed at room temperature. The sample of Tb:Lu₂O₃ was ground into powders for XRD measurement using an Ultima IV diffractometer from Japan. As shown in Fig. 1, the diffraction peaks of the Tb:Lu₂O₃ crystal are in very good accordance with the JCPDS card of pure Lu₂O₃ crystal. The lattice parameter of the Tb:Lu₂O₃ crystal was calculated to be 1.0424 nm, which is close to that of pure Lu₂O₃ (1.0391 nm), indicating that the doping of the Tb³⁺ ions into Lu₂O₃ did not affect the phase and crystal structure obviously. The concentration of terbium in Tb:Lu₂O₃ reached 1 at.% (i.e., 2.85 × 10²⁰ cm⁻³), which was measured by an ICP-AES (Ultima2, Jobin–Yvon). The absorption spectrum of Tb:Lu₂O₃ from 300 nm to 2400 nm with the resolution of 1 nm was measured by a spectrometer (Lambda900). The emission spectrum together with the decay curve of Tb:Lu₂O₃ was obtained by a fluorospectrophotometer (FSP920).

	Figure Option View Download New Window
	Fig. 1. Powder XRD pattern of Tb:Lu₂O₃ crystal.

3. Results and discussion

3.1. Absorption spectrum

The absorption spectra of the Tb:Lu₂O₃ crystal in the ranges of 320–495 nm and 1600–2400 nm are presented in Fig. 2. The absorption peaks centered around 328 nm, 331 nm, 339 nm, 342 nm, 344 nm, 349 nm, 353 nm, 355 nm, and 483 nm, corresponding to the transitions from ⁷F₆ to ⁵H₆, ⁵H₇+⁵D₀, ⁵L₉, ⁵G₄, ⁵G₅+⁵D₂, ⁵L₁₀, ⁵G₆, ⁵D₃, and ⁵D₄, respectively, are assigned and marked in Fig. 2(a). Figure 2(b) shows four absorption bands at 1752 nm, 1843 nm, 1906 nm, and 2075 nm, corresponding to the transitions from ⁷F₆ to ⁷F₀, ⁷F₁, ⁷F₂, and ⁷F₃, respectively. Some absorption bands overlap with each other due to the interaction of the crystal field. The absorption band around 483 nm corresponding to the ⁷F₆ → ⁵D₄ transition fits well with the emission wavelength of the InGaN laser diode.^[18] At the peak wavelength of 483 nm, its absorption cross-section σ_abs and FWHM are 3.5 × 10⁻²² cm² and 2.85 nm, respectively. For the Tb:Lu₂O₃ crystal, its σ_abs is larger than that of Tb:LiLuF₄ crystal (2.0 × 10⁻²² cm² at 488.8 nm for π-polarization)^[11] and the FWHM is larger than that of Tb:KYbW (only 1.0 nm for E ∥ N_m).^[19]

	Figure Option View Download New Window
	Fig. 2. Room temperature absorption spectrum of Tb:Lu₂O₃ crystal: (a) 320–495 nm, (b) 1600–2400 nm.

3.2. Judd–Ofelt analysis

The Judd–Ofelt (J–O) theory is a useful tool to calculate the 4f^N radiative transition intensities of lanthanide ions in various host materials. The detailed calculation process is the same with the literature.^[19–21] The refractive index formula of Lu₂O₃ and the transition matrix elements of Tb³⁺ ions required for the calculation are taken from Refs. [5], [19], and [22]. In our J–O theory analysis, six bands corresponding to the ⁷F₆ → ⁵L₁₀, ⁵G₆+⁵D₃, ⁵D₄, ⁷F₀+⁷F₁, ⁷F₂, and ⁷F₃ transitions are chosen to confirm the J–O intensity parameters. The parameters of the average wavelength , the refractive index n, the calculated line strengths S_cal, and the experimental line strengths S_exp are shown in Table 1. The small value of rms ΔS (0.011 × 10⁻²⁰ cm²) indicates that the fitting results between S_exp(J,J′) and S_cal(J,J′) could be considered as reasonable. The three J–O intensity parameters of Tb:Lu₂O₃ and Tb³⁺-doped other host materials are presented in Table 2. The parameter Ω₂ depends on the asymmetry and covalence of the lanthanide ions coordination field. The high value of Ω₂ means the increase of the covalent bonding and a higher asymmetry of the lanthanide ion site in host materials.^[23] As shown in Table 2, Ω₂ of Tb³⁺-doped Lu₂O₃ is 3.79, which is larger than that of NaPO₃–BaF₂–(GdF₃/TbF₃) and KYb(WO₄)₂, but smaller than that of CdF₂, TbAl₃(BO₃)₄, LiYF₄, and GAGSe, indicating that the covalent bonding and asymmetry of Tb³⁺ in Lu₂O₃ are higher than those of NaPO₃–BaF₂–(GdF₃/TbF₃) and KYb(WO₄)₂, but lower than those of CdF₂, TbAl₃(BO₃)₄, LiYF₄, and GAGSe. Furthermore, Ω₂ is relatively sensitive because of the admixing of the configuration, while Ω₄ and Ω₆ are less sensitive to the environment of the crystal field.^[23] As a spectroscopic quality factor, Ω₄/Ω₆ is generally used to predict the stimulated emission in laser hosts.^[21,24] For Tb:Lu₂O₃, Ω₄/Ω₆ is calculated to be 1.20, which is larger than that of most Tb³⁺-doped host materials listed in Table 2. This suggests that Tb:Lu₂O₃ is a very promising medium for the visible laser operation.

Table 1.

The average wavelength ( ), refractive index (n), experimental line strength S_exp(J,J′), and calculated line strength S_cal(J,J′) of Tb:Lu₂O₃ crystal.

Table 2.

Comparison of the J–O intensity parameters and the values of Ω₄/Ω₆ for Tb:Lu₂O₃ crystal and other Tb³⁺-doped materials.

For the Lu₂O₃ crystal, the radiative lifetime (τ_rad), fluorescence branching ratio (β), and spontaneous radiation transition probability (A) of ⁵D₄ multiplet of Tb³⁺ ions are calculated and shown in Table 3. Here, we mainly pay attention to the ⁵D₄ → ⁷F₅ transition emitting green light and the ⁵D₄ → ⁷F₄ transition emitting yellow light. The fluorescence branching ratio of the ⁵D₄ → ⁷F₅ transition is 65.89%, which is the largest one among the listed transitions in Table 3, indicating the high possibility of a green emission around 543 nm. For the ⁵D₄ → ⁷F₄ transition at 584 nm, the fluorescence branching ratio is 4.50%. In addition, the radiative lifetime τ_rad is 3.02 ms, larger than that of Tb:KYb(WO₄)₂ (2.08 ms)^[19] and Tb:CdF₂ (2.77 ms),^[21] suggesting the higher energy storage capability of the Tb:Lu₂O₃ crystal.

Table 3.

The spontaneous radiation transition probability (A), fluorescence branching ratio (β), and radiative lifetime (τ_rad) of Tb:Lu₂O₃ crystal.

3.3. Fluorescence spectrum

Excited by 483 nm, the room-temperature fluorescence spectrum of the Tb³⁺-doped Lu₂O₃ crystal is shown in Fig. 3, in which three observed emissions corresponding to the ⁵D₄ → ⁷F₅, ⁷F₄, and ⁷F₃ transitions are assigned and marked. The intensities of the three emission bands are in good agreement with the results of J–O analysis presented in Table 3. It can be seen that the ⁵D₄ → ⁷F₅ transition at 543 nm corresponding to green emission owns the largest emission cross-section (9.43 × 10⁻²² cm²) and the obtained FWHM is 4.15 nm. The emission cross-section is higher than that of Tb:KY₃F₁₀ (8.0 × 10⁻²² cm² at 545 nm)^[6] and Tb:LaF₃ (7.5 × 10⁻²² cm² at 543 nm).^[6] Furthermore, the emission cross-section of the yellow emission band at 584 nm corresponding to the ⁵D₄ → ⁷F₄ transition is 1.32 × 10⁻²² cm². The value is higher than that of Tb:PZABP (0.7 × 10⁻²² cm² at 582 nm),^[25] Tb:LBTAF (0.58 × 10⁻²² cm² at 585 nm),^[23] and Tb:TPP (1.0 × 10⁻²² cm² at 587 nm).^[26] The above data indicate that the Tb:Lu₂O₃ crystal is a promising candidate for a visible laser operation.

	Figure Option View Download New Window
	Fig. 3. Fluorescence spectrum of Tb:Lu₂O₃ crystal excited at 483 nm.

Excited at 483 nm, the fluorescence decay curve of ⁵D₄ level measured at room temperature is shown in Fig. 4. Obviously, it is single-exponential. The fluorescence lifetime τ_exp of ⁵D₄ level in the Tb:Lu₂O₃ crystal is fitted to be 1.13 ms. With the obtained radiative lifetime τ_rad (3.02 ms), the fluorescence quantum efficiency η (τ_exp/τ_red) of the Tb:Lu₂O₃ crystal is calculated to be 37.4%, which is comparable to that of Tb:KY₃F₁₀^[27] (38%) and higher than that of Tb:KYb(WO₄)₂^[19] (19%). Furthermore, with the concentration of Tb³⁺ ions decreasing from 2.0 mol% to 0.1 mol%, the quantum efficiency was reported to change from 46% to 93% in Tb:LBTAF.^[23] Hence, the quantum efficiency of the Tb:Lu₂O₃ crystal could also be optimized by changing the doped concentration of the Tb³⁺ ions.

	Figure Option View Download New Window
	Fig. 4. (color online) Fluorescence decay curve of ⁵D₄ level of Tb:Lu₂O₃ crystal.

4. Conclusion

Tb³⁺-doped Lu₂O₃ was successfully grown through the Fz method. The J–O theory was adopted to analyze the 4f^N radiative transitions of Tb³⁺ ions doped in Lu₂O₃. Around 483 nm, the absorption cross-section was obtained to be 3.5 × 10⁻²² cm² with an FWHM of 2.85 nm. As shown in the fluorescence spectrum, the ⁵D₄ → ⁷F₅ transition around 543 nm, corresponding to the green emission, has the largest emission cross-section of 9.43 × 10⁻²² cm² with the FWHM of 4.15 nm and the emission cross-section of the ⁵D₄ → ⁷F₄ transition around 584 nm, corresponding to the yellow emission, is 1.32 × 10⁻²² cm². With the fluorescence lifetime τ_exp of ⁵D₄ level fitted to be 1.13 ms and the radiative lifetime τ_rad of 3.02 ms, the fluorescence quantum efficiency was calculated to be 37.4%. These results reveal that the Tb:Lu₂O₃ crystal would be promising for green and yellow laser operations.

Reference

[1]	Gao J Zhang L Sun H X Dai X J Wu X D 2014 Opt. Commun. 319 110
[2]	Fang Q N Lu D Z Yu H H Zhang H J Wang J Y 2016 Opt. Lett. 41 1002
[3]	Nakamura S Mukai T Senoh M 1994 Appl. Phys. Lett. 64 1687
[4]	Zhang Y X Wang S X Alberto D L Yu G L Yu H H Zhang H J Mauro T Xu X G Wang J Y 2015 Chin. Phys. Lett. 32 054210
[5]	Carnall W T Fields P R Rajnak K 1968 J. Chem. Phys. 49 4447
[6]	Metz P W Marzahl D T Majid A Kränkel C Huber G 2016 Laser Photon. Rev. 10 335
[7]	Zhang S Hu Y Chen L Ju G Wang Z Lin J 2015 Opt. Mater. 47 203
[8]	Ji Z G Zhao S C Xiang Y Song Y L Ye Z Z 2004 Chin. Phys. 13 561
[9]	Liao J Qiu B Lai H 2009 J. Lumin. 129 668
[10]	Jenssen H P Castleberry D Gabbe D Linz A 1973 IEEE J. Quant. Elect. 9 665
[11]	Kränkel C Marzahl D T Moglia F Huber G Metz P W 2016 Laser Photon. Rev. 10 548
[12]	Pauling L Shappell M D 1930 Z. Kristallogr. 75 128
[13]	Peters V Bolz A Petermann K Huber G 2002 J. Cryst. Growth 879 237
[14]	Lindan P J D Gillan M J 1991 J. Phys.: Condens. Matter 3 3929
[15]	Fukuda T Chani V I 2007 Shaped Cryst.: Growth By Micro-Pulling-Down Technique Berlin Springer 8
[16]	McMillen C Thompson D Tritt T Kolis J 2011 Cryst. Growth. 11 4386
[17]	Fukabori A Chani V Kamada K Moretti F Yoshikawa A 2011 Cryst. Growth. 11 2404
[18]	Nakamura S Senoh M Nagahama S I Iwasa N Yamada T Matsushita T Sugimoto Y 1996 Jpn. J. Appl. Phys. 35 74
[19]	Loiko P Mateos X Dunina E Kornienko A Volokitina A Vilejshikova E Díaz F 2017 J. Lumin. 190 37
[20]	Zhang L Peng M Dong G Qiu J 2012 Opt. Mater. 34 1202
[21]	Boubekri H Diaf M Labbaci K Guerbous L Duvaut T Jouart J P 2013 J. Alloys Compd. 575 339
[22]	Kaminskii A A Akchurin M S Becker P Ueda K Bohatý L Shirakawa A Tokurakawa M Takaichi K Yagi H Dong J Yanagitani T 2008 Laser Phys. Lett. 5 300
[23]	Jamalaiah B C Kumar J S Babu A M Sasikala T Moorthy L R 2009 Physica B 404 2020
[24]	Jacobs R Weber M 1976 IEEE J. Quant. Elect. 12 102
[25]	Kesavulu C R Silva A C A Dousti M R Dantas N O Camargo A S S Catunda T 2015 J. Lumin. 165 77
[26]	Colak S Zwicker W K 1983 J. Appl. Phys. 54 2156
[27]	Zhang J Hao Z Zhang X Luo Y Ren X Wang X J Zhang J 2009 J. Appl. Phys. 106 034915
[28]	Kaminskii A A 1996 Cryst. Lasers: Phys. Processes Operating Schemes New York CRC Press 12
[29]	Shaw L B Cole B Thielen P A Sanghera J S Aggarwal I D 2001 IEEE J. Quant. Elect. 37 1127
[30]	Duhamel-Henry N Adam J L Jacquier B Linarés C 1996 Opt. Mater. 5 197