Spectroscopic Properties of pigment Li2-xZn1-xPrxTi3O8

Câmara, Maria Suely Costa da; Spinelli, Adaiane; Longo, Elson; Azevedo, Luciano Nobrega; Costa, Asenete Frutuoso; Pimentel, Patricia Mendonça; Melo, Dulce Maria de Araújo

doi:10.1590/1980-5373-MR-2015-0635

Abstract

Inorganic compounds doped with rare earths (Ce³⁺, Pr³⁺, Nd³⁺, Sm³⁺, Eu ³⁺, Gd ³⁺, Tb ³⁺, Tm³⁺⁾ have been used in various applications including light-emitting devices such as fluorescent lamps, cathode ray tubes, lasers and inorganic pigments. In this study, Pr³⁺ is doped in spinel Li₂ZnTi₃O₈ system and synthesized by the polymeric precursor method, which is based on the process developed by the Pechini, and characterized by X-ray diffraction, UV-visible and CIE-L colorimetric measures * a * b *., in order to study the effect of doping and thermal treatment on its colorimetric properties. With three different samples of Pr³⁺ doping (0.01; 0.05 and 0.1 mol%) were prepared and calcined at 500°C, 600°C, 700°C, 800°C and 900°C for 4 h. The analysis of X-ray diffraction confirmed the formation of pure phases with spinel structure and average crystallite size of less than 46 nm. It was found that the colorimetric properties ranging from green to red, in accordance with the increase in the concentration of Pr³⁺ and thermal processing temperature.

Keywords
Ceramics; inorganic compounds; nanostructures; chemical synthesis; X-ray diffraction

1. Introduction

Inorganic compounds doped with trivalent rare earth (RE) ions (Ce³⁺, Pr³⁺, Nd³⁺, Sm³⁺, Eu³⁺, Gd³⁺, Tb³⁺, Tm³⁺⁾ have been used in many different applications, including luminescent devices such as fluorescent lamps, cathode ray tubes and lasers. In these applications are particularly preferred ions displaying 4fⁿ transitions¹1 Dorenbos P. The 4fn↔4fn-15d Transitions of the Trivalent Lanthanides in Halogenides and Chalcogenides. Journal of Luminescence. 2000;91(1-2):91-106.^,²2 Barros BS, Melo SP, Gama L, Alves-Jr S, Fagury-Neto E, Kiminami RHGA, et al. Caracterização morfológica e luminescente de nanopartículas de aluminato de zinco dopadas com Eu3+. Cerâmica. 2005;51(317):63-69.. Among the rare earth ions, trivalent praseodymium shows a particular feature due to close energy separation between the low edge of the 4f5d configuration and the ¹S₀ level of the 4f² configuration. The radiative de-excitation between these two configurations gives rise a broad band emissions between 220 and 450 nm approximately, depending on the host lattice³3 Nicolas S, Descroix E, Guyoto Y, Ejoubert M, Pédrini C, Ovanesyan ZKL, et al. Spectroscopic and colour centre studies of Pr-doped LuAlO3. Optical Materials. 2002;19(1):129-137.. Moreover, emitting species can be excited, either directly or by two-step excitation processes related to the ³P₀ or ¹D₂ metastable intermediate levels, located in the blue or orange spectral domains, respectively. The two-steps excitation of the 4f5d states of Pr³⁺ ions has been demonstrated in YAlO₃:Pr³⁺ crystals, as well as in fluoride crystals such as KY₃F₁₀:Pr³⁺, BaY₂F₈:Pr³⁺, LiYF₄:Pr³⁺ and LiLuF₄:Pr³⁺.

The Pr³⁺ emission spectra strongly depend on the crystalline field which the ion is allocated. For instance, while Gd₂O₂S:Pr³⁺ emits green color due to the ³P₀ → ³H₄ transition, LiYF₄:Pr³⁺ displays a red color associated to the ³P₀ → ³H₆, ³F₂ transitions³. The chromatic properties of rare earth sesquisulfides Ln₂S₃ and Aln₂S₄ (A = Ca, Sr) have been recently investigated. These compounds exhibit pronounced color, ranging from yellow to red depending on the rare earth. The color of these compounds has been related to various energetic parameters, such as ionization energies, crystal field splitting or nephelauxetic effect, the positions of the energy levels at the valence and the conduction bands, which are a function of the crystal structure⁵5 Demourgues A, Tressaud A, Laronze H, Macaudiére P. Rare earth fluorosulfides LnSF and Ln2AF4S2 as new colour pigments. Journal of Alloys and Compounds. 2001;323-324:223-230.. Metal oxides have been extensively used as host matrices due to their much better chemical stability than conventional sulfide compounds. The spinel structure is an interesting class of oxides with general formula AB₂O₄ which can act as a host matrix for rare earth ions. A refers to cations in tetrahedral sites and B represents the cations in the octahedral positions. It is a cubic structure with space group symmetry Fd3m⁶. This elaborate crystallographic structure, which can accommodate significant cation disorder, has a unique perspective for studies of substitutions and their relations with the chemical and physical properties⁷7 Barth TFW, Posnjak E. The spinel structure: example of variate atoms equipoints. Journal of the Washington Academy of Sciences. 1931;21:255-258.^,⁸8 Sickafus KE, Wills JM, Grimes NW. Structure of Spinel. Journal of the American Ceramic Society. 1999;82(12):3279-3292.. Spinel crystal structures can be divided into two types: normal (or direct) and inverse spinel. In the normal spinels, the A²⁺ ions are contained in the tetrahedral holes, and the B³⁺ in the octahedral holes. In the inverse spinels, on the other hand, the A²⁺ ions and half the B³⁺ ions are in octahedral holes, and the remaining B³⁺ ions are in tetrahedral holes⁹9 Shriver DF, Atkins PW, Langford CH. Inorganic Chemistry. 2nd ed. Oxford: Oxford University Press; 1994. 819p.

10 Lisboa-Filho PN, Gama L, Paiva-Santos CO, Varela JA, Ortiz WA, Longo E. Crystallographic and magnetic structure of polycrystalline Zn 7- x Ni x Sb 2 O 12 spinels. Materials Chemistry and Physics. 2000;65(2):208-211.

11 Braun PB. A Superstructure in Spinels. Nature. 1952;170:1123.^-¹²12 Diallo PT, Boutinaud P, Mahiou R, Cousseins JC. Red Luminescence in Pr3+-Doped Calcium Titanates. Physica Status Solidi. 1997;160(1):255-263. In fact, very few spinels have exactly the normal or inverse structure, and these are sometimes called mixed spinels. Li₂ZnTi₃O₈ presents a derived spinel structure with P4₃32 space group, in which the octahedral 12d and 4b sites are occupied by Ti and Li respectively, and the tetrahedral 8c sites are shared by Zn and Li, suggesting an intermediary spinel structure¹³13 Câmara MSC, Lisboa-Filho PN, Cabrelon MD, Gama L, Ortiz WA, Paiva-Santos CO, et al. Synthesis and characterization of Li2ZnTi3O8 spinel using the modified polymeric precursor method. Materials Chemistry and Physics. 2003;82(1):68-72.

14 Câmara MSC, Gurgel MFC, Lazaro SR, Bochi TM, Pizani OS, Beltran A, et al. Room temperature photoluminescence of the Li2ZnTi3O8 spinel: Experimental and theoretical study. International Journal of Quantum Chemistry. 2005;103(5):580-587.^-¹⁵15 Lucena PR, Pontes FM, Pinheiro CD, Longo E, Pizani OS, Lázaro S, et al. Fotoluminescência em materiais com desordem estrutural. Cerâmica. 2004;50(314):138-144..

The present paper presents an optical properties study of the Li_2-xZn_1-xPr_xTi₃O₈ spinels, where x = 0.01; 0.05 and 0.1 mol%, synthesized by the Pechini method¹⁴14 Câmara MSC, Gurgel MFC, Lazaro SR, Bochi TM, Pizani OS, Beltran A, et al. Room temperature photoluminescence of the Li2ZnTi3O8 spinel: Experimental and theoretical study. International Journal of Quantum Chemistry. 2005;103(5):580-587.. This study was based on analyses of diffuse reflectance and colorimetric coordinates and focused in the energy levels of the Pr³⁺ ions. It should be emphasized that no publication was found in the literature about the energy levels of the Pr³⁺ ions in the Li₂ZnTi₃O₈ host lattice.

2. Experimental Procedure

The polymeric precursor solution was prepared by the Pechini method¹⁶16 Pechini MP, inventor. Sprague Electric Co. Method of preparing lead and alkaline earth titanates and niobates and coating method using the same to form a capacitor. US Patent. 3.330.697. 1967., which has been used to synthesize polycationic powders. The process is based on the metallic citrate polymerization using ethylene glycol in order to promote polymerization of the metallic citrate. Due to the formation of high viscosity polyester, the segregation of the cations during thermal decomposition is minimal¹⁷17 Paris EC, Leite ER, Longo E, Varela JA. Synthesis of PbTiO3 by use of polymeric precursors. Materials Letters. 1998:37(1-2):1-5.. A hydrocarboxylic acid, such as citric acid, is used to chelate cations in an aqueous solution. The addition of a glycol such as ethylene glycol leads to the formation of an organic ester. Polymerization, promoted by heating the mixture, results in a homogeneous resin in which metal ions are uniformly distributed throughout the organic matrix.

The polymeric precursor aqueous solution was prepared using the 3:1 molar ratio between citric acid and metallic cations. First, a citric acid solution was kept under stirring for 5 min at 70°C, then lithium carbonate (Li₂CO₃, Merck), zinc acetate dihydrate (Zn(CH₃CO₂)₂.2H₂O, Aldrich) and praseodymium carbonate (Pr₂(CO₃)₃, Nuclemon) were added to the solution and kept under stirring until their complete dissolution. Subsequently, ethylene glycol (HOCH₂CH₂OH, Merck) was added in a ratio of 2:3 in relation to the citric acid and stirred vigorously for 10 min at 100°C to promote polyesterification reactions and water evaporation, which lead to formation of a polymeric resin. The resin was heat treated at 300°C for 3 h, and then the obtained powder was ground in a mortar and calcined in air at 500, 600, 700, 800 and 900°C for 4 h.

The produced powders were characterized by XRD using a Siemens D5000 equipment operating with Cu Kα radiation. The data were collected in the range 5-100º (2θ), step size of 0.02º and count time of 10 s per step. UV-vis-NIR spectroscopy (diffuse reflectance) of the samples was performed with a Varian 5G spectrophotometer. In addition, the L*, a* and b* color parameters and diffuse reflectance were measured by a Gretac Macbeth Color-eye spectrophotometer 2180/2180 UV, in the 300-800 nm range, using the D65 illumination. The CIE-L*a*b* colorimetric method, recommended by the CIE was followed. In this method, L* is the lightness axis [black (0)→ white (100)], b* is the blue (-) → yellow (+) axis, and a* is the green (-) → red (+) axis, and ΔE is the hue variation.

3. Results and discussion

The X-ray diffraction patterns confirmed the presence of a single pure phase with spinel-type structure, Li₂ZnTi₃O₈, for all samples treated at the 500-900°C temperature range, independently of the Pr³⁺ ions concentration (Figure 1). These results suggest that Pechini method is able to produce oxide powders with a high crystallinity and nanometric size crystallites. It was also observed crystallite size increases when the heat-treatment temperature increases (Figure 2).

Figure 1
XRD patterns of the Li₂ZnTi₃O₈ spinel doped with: (a) 0.01% mol % of Pr³⁺, (b) 0.05 mol% of Pr³⁺, (c) 0.1mol % in Pr³⁺.

Figure 2
Effect of the calcinations temperature on the crystallite size of the spinel phase.

Figure 3 presents the diffuse reflectance of Li₂ZnTi₃O₈ doped with 0.01, 0.05 and 0.1 mol% of Pr³⁺ ions and calcined at 500, 600, 700, 800 and 900°C. It can be seen by the spectra that the spinel phase presents absorption bands at the spectral domains ranging from blue to yellow. The CIE- L*a*b* chromatic coordinates are depicted in Figure 4. It is noticed that the color of the spinel phase is more intense, toward the direction of the green, when the Pr³⁺ ions concentration increases. On the other hand, the color becomes darker when the calcination temperature raises and the compounds become more crystalline (Figure 4a).

Figure 3
Diffuse reflectance of the Li₂ZnTi₃O₈ spinel, calcined at the 500-900°C temperature range, and doped with Pr³⁺ (a) 0.01mol%, (b)0.05mol% and (c) 0.1mol%.

Figure 4
Chromatic coordinates of the of the Li₂ZnTi₃O₈ spinel doped with Pr³⁺ (a)"L" and (b) a*.

Figure 5 illustrates the diffuse reflectance of the spinel calcined at 800°C for different concentrations of dopant. The spectra obtained at room temperature showed the 4f² Stark levels characteristic of Pr³⁺ ions which are presented in Table 1. It is noticed for all samples the characteristic spectral lines of Pr³⁺ ions in the range from 1.75 to 3 eV, attributed to intercon figurational transitions of RE 4f^n-15d→4fⁿ ions, due to the strong coupling between the 5d electrons of the active ion and the host lattice⁹9 Shriver DF, Atkins PW, Langford CH. Inorganic Chemistry. 2nd ed. Oxford: Oxford University Press; 1994. 819p.. It is well known that Pr³⁺ ion energy levels are shifted toward lower energies when in the presence of a crystalline field. Usually, the difference between the energy levels of the rare earth ion when isolated and into a crystalline field (ΔE) is higher than 500 cm^-1. It was found (Table 1) that Pr³⁺ ions presents greater ΔE when placed into a spinel-type host lattice than into LiYF₄ and LiLuF₄ compounds, however, smaller than into a LuAlO₃ compound. All these results lead to the energy level scheme presented in Figure 6.

Figure 5
Diffuse reflectance of the Li₂ZnTi₃O₈ spinel doped with Pr³⁺ (a) 0.01, 0.05 and 0.1 mol% (b) amplification of the 0.1% curve, calcined at 800°C.

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Table 1
Crystal field splitting of the ^2s+1L_j manifolds of Pr³⁺ ion in Li₂ZnTi₃O₈, LiYF₄, LiLuF₄ and LuAlO₃.

Figure 6
Energy level diagram of Pr ³⁺ in Li₂ZnTi₃O₈, obtained from absorption spectra.

4. Conclusions

We have demonstrated that Li_2-xZn_1-xPr_xTi₃O₈ nanocrystalline powders can be successfully synthesized by a polymer precursor method. These compounds showed a green color directly related to the Pr³⁺ ion concentration. By using a simple technique of diffuse reflectance it was possible to determinate the positions of the Stark 4f² levels of the Pr³⁺ ion in the Li_2-xZn_1-xPr_xTi₃O₈ host lattice. It was found that the spinel Li_2-xZn_1-xPr_xTi₃O₈ is a promising material to be used as fluorescent material and/or a pigment.

5. Acknowledgements

The authors gratefully acknowledge the financial support of the Brazilian research agencies FAPESP, PRONEX, FINEP, CNPq E FACEPE.

6. References

¹
Dorenbos P. The 4fⁿ↔4f^n-15d Transitions of the Trivalent Lanthanides in Halogenides and Chalcogenides. Journal of Luminescence 2000;91(1-2):91-106.
²
Barros BS, Melo SP, Gama L, Alves-Jr S, Fagury-Neto E, Kiminami RHGA, et al. Caracterização morfológica e luminescente de nanopartículas de aluminato de zinco dopadas com Eu3+. Cerâmica 2005;51(317):63-69.
³
Nicolas S, Descroix E, Guyoto Y, Ejoubert M, Pédrini C, Ovanesyan ZKL, et al. Spectroscopic and colour centre studies of Pr-doped LuAlO₃ Optical Materials 2002;19(1):129-137.
⁴
Sinha SP, ed. Systematics and the Properties of the Lanthanides Dordrecht: Springer; 1983.
⁵
Demourgues A, Tressaud A, Laronze H, Macaudiére P. Rare earth fluorosulfides LnSF and Ln₂AF₄S₂ as new colour pigments. Journal of Alloys and Compounds 2001;323-324:223-230.
⁶
Poleti D, Vasović D, Karanović LJ, Branković Z. Synthesis and Characterization of Ternary Zinc-Antimony-Transition Metal Spinels. Journal of Solid State Chemistry 1994;112(1):39-44.
⁷
Barth TFW, Posnjak E. The spinel structure: example of variate atoms equipoints. Journal of the Washington Academy of Sciences 1931;21:255-258.
⁸
Sickafus KE, Wills JM, Grimes NW. Structure of Spinel. Journal of the American Ceramic Society 1999;82(12):3279-3292.
⁹
Shriver DF, Atkins PW, Langford CH. Inorganic Chemistry 2nd ed. Oxford: Oxford University Press; 1994. 819p.
¹⁰
Lisboa-Filho PN, Gama L, Paiva-Santos CO, Varela JA, Ortiz WA, Longo E. Crystallographic and magnetic structure of polycrystalline Zn 7- x Ni x Sb 2 O 12 spinels. Materials Chemistry and Physics 2000;65(2):208-211.
¹¹
Braun PB. A Superstructure in Spinels. Nature 1952;170:1123.
¹²
Diallo PT, Boutinaud P, Mahiou R, Cousseins JC. Red Luminescence in Pr³⁺-Doped Calcium Titanates. Physica Status Solidi 1997;160(1):255-263.
¹³
Câmara MSC, Lisboa-Filho PN, Cabrelon MD, Gama L, Ortiz WA, Paiva-Santos CO, et al. Synthesis and characterization of Li₂ZnTi₃O₈ spinel using the modified polymeric precursor method. Materials Chemistry and Physics 2003;82(1):68-72.
¹⁴
Câmara MSC, Gurgel MFC, Lazaro SR, Bochi TM, Pizani OS, Beltran A, et al. Room temperature photoluminescence of the Li₂ZnTi₃O₈ spinel: Experimental and theoretical study. International Journal of Quantum Chemistry 2005;103(5):580-587.
¹⁵
Lucena PR, Pontes FM, Pinheiro CD, Longo E, Pizani OS, Lázaro S, et al. Fotoluminescência em materiais com desordem estrutural. Cerâmica 2004;50(314):138-144.
¹⁶
Pechini MP, inventor. Sprague Electric Co. Method of preparing lead and alkaline earth titanates and niobates and coating method using the same to form a capacitor. US Patent. 3.330.697. 1967.
¹⁷
Paris EC, Leite ER, Longo E, Varela JA. Synthesis of PbTiO3 by use of polymeric precursors. Materials Letters 1998:37(1-2):1-5.

Erratum

In the article "Spectroscopic Properties of pigment Li2-xZn1-xPrxTi3O8", DOI number: http://dx.doi.org/10.1590/1980-5373-MR-2015-0635, published in Mat. Res., 2016, in the first page where the author's names were:

Maria Suely Costa da Câmara^a*, Adaiane Spinelli^b , Elson Longo^c, Luciano Nobrega Azevedo^d, Asenete Frutuoso Costa^e, Patricia Mendonça Pimentel^f, Dulce Araújo Freitas Melo^d

It should be written:

Maria Suely Costa da Câmara^a*, Adaiane Spinelli^b , Elson Longo^c, Luciano Nobrega Azevedo^d, Asenete Frutuoso Costa^e, Patricia Mendonça Pimentel^f, Dulce Maria de Araújo Melo^d

Publication Dates

Publication in this collection
14 June 2016
Date of issue
Jul-Aug 2016

History

Received
20 Oct 2015
Reviewed
03 Apr 2016
Accepted
23 May 2016

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ¹
Dorenbos P. The 4fⁿ↔4f^n-15d Transitions of the Trivalent Lanthanides in Halogenides and Chalcogenides. Journal of Luminescence 2000;91(1-2):91-106.

[2] ²
Barros BS, Melo SP, Gama L, Alves-Jr S, Fagury-Neto E, Kiminami RHGA, et al. Caracterização morfológica e luminescente de nanopartículas de aluminato de zinco dopadas com Eu3+. Cerâmica 2005;51(317):63-69.

[3] ³
Nicolas S, Descroix E, Guyoto Y, Ejoubert M, Pédrini C, Ovanesyan ZKL, et al. Spectroscopic and colour centre studies of Pr-doped LuAlO₃ Optical Materials 2002;19(1):129-137.

[4] ⁴
Sinha SP, ed. Systematics and the Properties of the Lanthanides Dordrecht: Springer; 1983.

[5] ⁵
Demourgues A, Tressaud A, Laronze H, Macaudiére P. Rare earth fluorosulfides LnSF and Ln₂AF₄S₂ as new colour pigments. Journal of Alloys and Compounds 2001;323-324:223-230.

[6] ⁶
Poleti D, Vasović D, Karanović LJ, Branković Z. Synthesis and Characterization of Ternary Zinc-Antimony-Transition Metal Spinels. Journal of Solid State Chemistry 1994;112(1):39-44.

[7] ⁷
Barth TFW, Posnjak E. The spinel structure: example of variate atoms equipoints. Journal of the Washington Academy of Sciences 1931;21:255-258.

[8] ⁸
Sickafus KE, Wills JM, Grimes NW. Structure of Spinel. Journal of the American Ceramic Society 1999;82(12):3279-3292.

[9] ⁹
Shriver DF, Atkins PW, Langford CH. Inorganic Chemistry 2nd ed. Oxford: Oxford University Press; 1994. 819p.

[10] ¹⁰
Lisboa-Filho PN, Gama L, Paiva-Santos CO, Varela JA, Ortiz WA, Longo E. Crystallographic and magnetic structure of polycrystalline Zn 7- x Ni x Sb 2 O 12 spinels. Materials Chemistry and Physics 2000;65(2):208-211.

[11] ¹¹
Braun PB. A Superstructure in Spinels. Nature 1952;170:1123.

[12] ¹²
Diallo PT, Boutinaud P, Mahiou R, Cousseins JC. Red Luminescence in Pr³⁺-Doped Calcium Titanates. Physica Status Solidi 1997;160(1):255-263.

[13] ¹³
Câmara MSC, Lisboa-Filho PN, Cabrelon MD, Gama L, Ortiz WA, Paiva-Santos CO, et al. Synthesis and characterization of Li₂ZnTi₃O₈ spinel using the modified polymeric precursor method. Materials Chemistry and Physics 2003;82(1):68-72.

[14] ¹⁴
Câmara MSC, Gurgel MFC, Lazaro SR, Bochi TM, Pizani OS, Beltran A, et al. Room temperature photoluminescence of the Li₂ZnTi₃O₈ spinel: Experimental and theoretical study. International Journal of Quantum Chemistry 2005;103(5):580-587.

[15] ¹⁵
Lucena PR, Pontes FM, Pinheiro CD, Longo E, Pizani OS, Lázaro S, et al. Fotoluminescência em materiais com desordem estrutural. Cerâmica 2004;50(314):138-144.

[16] ¹⁶
Pechini MP, inventor. Sprague Electric Co. Method of preparing lead and alkaline earth titanates and niobates and coating method using the same to form a capacitor. US Patent. 3.330.697. 1967.

[17] ¹⁷
Paris EC, Leite ER, Longo E, Varela JA. Synthesis of PbTiO3 by use of polymeric precursors. Materials Letters 1998:37(1-2):1-5.

^SL_j	V(cm^-1) Pr³⁺	V(cm^-1) Li₂ZnTi₃O₈	V(cm^-1) LiYF₄	V(cm^-1) LiLuF₄	V(cm^-1) LuAlO₃
¹G₄		14806 (^c c = 0.1% Pr3+ )
¹D₂	17334	16570 (^a a = 0.01% Pr 3+, ) 16619 (^c c = 0.1% Pr3+ ) 16554 (^c c = 0.1% Pr3+ ) 16724 (^c c = 0.1% Pr3+ ) 17314 (^c c = 0.1% Pr3+ ) 17331 (^c c = 0.1% Pr3+ ) 16619 (^b b = 0.05% Pr3+, ) ΔE (515)	16740 ΔE (594)	16812 ΔE (522)	16337 ΔE (997)
³P₀	21390	19240 (^a a = 0.01% Pr 3+, ) 20656 (^b b = 0.05% Pr3+, ) 20640 (^c c = 0.1% Pr3+ ) ΔE (1241)	20860 ΔE (530)	20864 ΔE (526)	20361 ΔE (1029)
³P₁	22007	20430 (^a a = 0.01% Pr 3+, ) 21222 (^b b = 0.05% Pr3+, ) 20890 (^c c = 0.1% Pr3+ ) ΔE (1159)	............	21414 ΔE (593)	20471 ΔE (1536)
¹I₆	22212	21069 (^a a = 0.01% Pr 3+, ) 22169 (^b b = 0.05% Pr3+, ) 21093 (^c c = 0.1% Pr3+ ) ΔE (769)	.............	21825 ΔE (387)	21105 ΔE (1107)
³P₂	23161	22258 (^a a = 0.01% Pr 3+, ) 22250 (^c c = 0.1% Pr3+ ) ΔE (907)	22498 ΔE (663)	22521 ΔE (640)	21935 ΔE (1216)

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