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Article

Europium (II)-Doped CaF2 Nanocrystals in Sol-Gel Derived Glass-Ceramic: Luminescence and EPR Spectroscopy Investigations

1
National Institute of Materials Physics, Atomistilor 405A, 077125 Magurele, Romania
2
National Institute for Research and Development of Isotopic and Molecular Technologies, Donat 67-103, 400293 Cluj-Napoca, Romania
*
Author to whom correspondence should be addressed.
Nanomaterials 2022, 12(17), 3016; https://doi.org/10.3390/nano12173016
Submission received: 21 July 2022 / Revised: 26 August 2022 / Accepted: 29 August 2022 / Published: 31 August 2022
(This article belongs to the Special Issue Recent Developments in Luminescent Nanomaterials)

Abstract

:
The remarkable properties of Eu2+-activated phosphors, related to the broad and intense luminescence of Eu2+ ions, showed a high potential for a wide range of optical-related applications. Oxy-fluoride glass-ceramic containing Europium (II)-doped CaF2 nanocrystals embedded in silica matrix were produced in two steps: glass-ceramization in air at 800° with Eu3+-doped CaF2 nanocrystals embedded followed by Eu3+ to Eu2+ reduction during annealing in reducing atmosphere. The broad, blue luminescence band at 425 nm and with the long, weak tail in the visible range is assigned to the d → f type transition of the Eu2+ located inside the CaF2 nanocrystals in substitutional and perturbed sites, respectively; the photoluminescence quantum yield was about 0.76. The X-ray photoelectron spectroscopy and Electron paramagnetic spectroscopy confirmed the presence of Eu2+ inside the CaF2 nanocrystals. Thermoluminescence curves recorded after X-ray irradiation of un-doped and Eu2+-doped glass-ceramics showed a single dominant glow peak at 85 °C related to the recombination between F centers and Eu2+ related hole within the CaF2 nanocrystals. The applicability of the procedure can be tested to obtain an oxy-fluoride glass-ceramic doped with other divalent ions such as Sm2+, Yb2+, as nanophosphors for radiation detector or photonics-related applications.

1. Introduction

Rare-earth (RE) doped oxyfluoride nano-glass ceramics where the optically active RE3+-ions are incorporated into the precipitated fluoride nanocrystals showed high potential for optical-related applications due to their features such as high transparency and remarkable luminescence properties ([1,2] and references therein). Through a controlled nucleation and crystallization processes of the initial glass, the partition of the optically active RE3+-ions into the precipitated fluoride nanocrystals is obtained. Special attention was focused on optical properties of oxyfluoride nano-glass ceramics containing CaF2 nanocrystals, in particular doping with Eu3+ as a red-light luminescent ion [3,4,5,6,7,8]. It was shown that the glass-ceramic samples obtained by a melt-quenching technique showed luminescence features of both Eu2+ and Eu3+ ion species, and the Eu3+ ions are incorporated into the non-centrosymmetric sites of CaF2 nanocrystals and shows stronger emission than in the initial glass [4,5].
Sol-gel chemistry (using metal alkoxides and involving trifluoroacetic acid as an in-situ fluorination reagent) offers a flexible synthesis approach for the synthesis of RE3+-doped glass-ceramic and a wide compositional range ([9,10] and references therein). Up to now, the research efforts of oxy-fluoride glass-ceramics were focused on optical properties related to the trivalent RE3+-doped luminescent nanocrystals [10]. In particular, the optical properties of Eu3+ sol-gel derived glass-ceramic are quite similar to those obtained by melt-quenching [3,4,5] except that only the Eu3+ ions luminescence is observed [11,12]. Nevertheless, despite numerous studies, the sol-gel synthesis of oxy-fluorides nano-glass ceramics doped with optically active bivalent RE2+ -ions (such as Eu2+ and Sm2+) has not been reported in the literature. Previous investigations [13,14] have shown the incorporation of the reduced Eu2+ and Sm2+ ions in sol-gel glasses (not ceramic ones) under moderate temperature and atmospheric conditions in two steps, glass-formation and their reduction to the bivalent state by calcination in a reducing atmosphere.
The optical performances of Eu2+-activated phosphors have attracted significant attention because of the remarkable properties related to the broad and intense luminescence of Eu2+ ions. These phosphors are widely applied in various fields: lighting and display areas, scintillator detectors, X-ray storage phosphors for digital imaging applications, and persistent phosphors [15,16,17]. The optical performances are related to the broad and intense Eu2+ ion fluorescence, which is due to the 5d-4f parity allowing transition and is strongly dependent on the host lattice. In particular, there is an increased interest in CaF2:Eu2+ phosphor and several studies reporting various synthesis methods [18,19,20] and optical properties: scintillation, particles detection, and dosimeter properties [21,22,23].
Within the present study, we investigated and demonstrated the possibility to produce Europium (II)-doped CaF2 nanocrystals embedded in a silica matrix by using controlled reduction of Eu(III)-doped SiO2-CaF2 glass ceramics. We investigated the Eu(II) ions species and related properties using optical and magnetic resonance techniques: photoluminescence (PL) spectroscopy, quantum efficiency, thermoluminescence (TL), and electron paramagnetic resonance (EPR) spectroscopy.

2. Materials and Methods

2.1. Samples Preparation

For the preparation of the Eu3+(1%)-doped (94SiO2–5CaF2) (mol%) bulk xerogels, we used the sol-gel synthesis route according to the method described in Ref. [24] with reagent grade of tetraethylorthosilicate (TEOS), trifluoroacetic acid (TFA), ethyl alcohol, acetic acid (Alpha Aesar, Massachusetts, USA), and deionized water were used as starting materials. The TEOS was diluted with an equal volume of ethyl alcohol and then hydrolyzed with water under constant stirring. Calcium acetate and Europium (III) acetate hydrate were dissolved in a TFA aqueous solution. The TFA and TEOS solutions were then mixed, and acetic acid was added as a catalyst. For the TEOS:Ca(CH3COO)2:Eu(CH3COO)3∙xH2O:TFA:H2O:CH3COOH molar ratio, we used 19:1:0.2:3:90:3. The as-obtained sol was stirred and aged at room temperature in a sealed container, followed by drying at up to 120 °C to form the xerogel. Glass-ceramics have been obtained after annealing the dried xerogel at 800 °C for 1 h in air and subsequently in reducing atmosphere, for another hour, in 5H2-95Ar gas flow. After the preparation, the xerogel was clear-transparent, but, after annealing, the glass samples became milky white due to the crystallization and crushes.

2.2. Samples Characterization

For the thermal analysis, we have used a SETARAM Setsys Evolution 18 Thermal Analyzer (Setaram Instrumentation, Caluire-et-Cuire, France) in the 75 to 900 °C temperature range, in synthetic air (80% N2/20% O2) at a standard heating rate of 10 °C/min. Structural characterization was performed by X-ray diffractometry (XRD) and a Bruker D8 Advance type X-ray diffractometer (Billerica, MA, USA), in focusing geometry, equipped with a copper target X-ray tube and a LynxEye one-dimensional detector. The XRD pattern was recorded in the 20 to 70° range with a 0.05° step and 2 s integration time. For the phase composition and crystallographic characteristics, the XRD patterns were analyzed using the Powercell dedicated software [25]. Energy dispersive X-ray (EDX) analysis was carried out by using a Zeiss MERLIN (Jena, Germany) Compact scanning electron microscope (SEM) with a GEMINI column equipped with an energy dispersive X-ray system analyzer. The X and Q-band Electron Paramagnetic Resonance (EPR) spectroscopy measurements were carried out with a continuous-wave Elexsys 500 EPR spectrometer (Bruker AXS GmbH, Karlsruhe, Germany) equipped with a Bruker X-SHQ 4119HS-W1 X-band resonator and an ER 5106 QT-W Q-band resonator. For the X-ray photoelectron spectroscopy (XPS) measurements, we used a multianalysis SPECS system in ‘Large Area Mode’ of the XPS analyzer with very low angular acceptance, of 5° around the normal. The non-monochromatic source used an Al anode (Ex = 1486.6 eV) with an FWHM (Full Width at Half Maximum) of 0.3 eV that provided a uniform X-Ray flux on the sample surface. The electron analyzer was a PHOIBOS150 with a 150 mm radius and nine channeltron detector. The spectra were recorded with a Pass Energy of 10 eV and the extended spectra with a Pass Energy of 50 eV. In order to minimize the additional shadowing and differential charging effects, we used a dedicated flood gun Specs FG15/40.
The photoluminescence and excitation spectra were recorded at room temperature using a FluoroMax 4P spectrophotometer (HORIBA Jobin Yvon, Kyoto, Japan). We used the Quanta-Phy accessory for the quantum yield (QY) and chromaticity analysis.

3. Results and Discussion

3.1. Thermal Analysis

Thermogravimetry (TG) and differential scanning calorimetry (DSC) curves recorded on undoped SiO2-CaF2 xerogel (Figure 1) show a thermal degradation profile with several stages related to the glass ceramization [26]. The first one up to about 150 °C was associated with desorption of ethanol and water as well as acetic acid. A second weight loss up to about 350 °C is accompanied by a strong DSC peak at about 325 °C and is related to the Ca trifluoroacetate decomposition [24,27,28] with the formation of tiny CaF2 nanocrystalline seeds (a few nm size) [24,29,30]. A weaker weight loss in the 400 to 500 °C temperature range is related to the pyrolysis of organic groups. At even higher temperatures, we observed a weaker DSC peak at 663 °C, which is assigned to the initial nanocrystals’ separation, growth, and crystallinity improvement [26,28,29]. The peak assignment is consistent with its dependence on the nature of the nanocrystalline phase: at 685 °C in 95SiO2–5BaF2 [28] and 700 °C in 95SiO2–5SrF2 [30].

3.2. Structural Analysis

The XRD patterns of Eu-doped (95SiO2–5CaF2) glass-ceramics presented in Figure 2 show extra-diffraction peaks assigned to the CaF2 nanocrystalline cubic phase precipitation in the glass matrix superimposed on a broad background due to the amorphous silica [12]. The presence of CaF2 nanocrystals embedded in the glassy matrix was previously confirmed by the transmission electron microscopy (Figure 3). From the XRD pattern analysis of Eu3+-doped glass-ceramic (annealed in air), we extracted the lattice parameter a = 5.515 Å and the nanocrystal size of about 27 nm. The lattice parameter is different from a = 5.465 Å of the undoped glass-ceramic crystal and is consistent with the expansion of the crystalline lattice of about 1%.
The EDX spectra analysis of the glass-ceramic sample (Figure S1, supporting material) indicated the presence of elements from the precursor chemicals: 2 at%(C), 28 at%(Si), 53 at%(O), 1.5 at%(Ca), 15 at%(F), and 0.5 at%(Eu). It also indicated the presence of oxygen in the nanocrystals [31,32] that can be responsible for the lattice distortion. The incorporation of the nonbonding oxygen ions of the silica matrix [12,33] and the interstitial fluorine ions compensate for the excess positive charge caused by the Eu3+ doping and enlarges the crystal lattice as was observed in the nanocrystalline powders [34,35]. Hence, the ionic environment strongly influences the nanocrystal growth process in the silica matrix. Further annealing in reducing atmosphere does not change the lattice parameter a = 5.514 Å, and the nanocrystals’ mean size of about 26 nm. The nanocrystals’ size remains almost unchanged due to the interfacial interaction of SrF2 nano-crystals with the glass matrix, which hinders their further growth [25].

3.3. Optical Properties: Photoluminescence and Colorimetric Analysis

The luminescence properties of the europium ion strongly depend on the valence state (Eu2+ or Eu3+) and the matrix state, crystalline or amorphous. The Eu3+ luminescence is characterized by sharp peaks structured by the crystalline field (in the crystalline materials) and are assigned to the 4f → 4f transitions between various excited states and 5F0 ground state. On the other hand, Eu2+ luminescence has a broadband character, is strongly dependent on the host lattice, and occurs as the lowest crystal-field component of the 4f65d excited configuration to the 8S7/2 ground state (parity-allowed) [36].
The PL and PL excitation spectra of Eu2+/ Eu3+-doped SiO2-CaF2 glass-ceramic samples are presented in Figure 4. The PL spectra recorded on glass-ceramic annealed in air shows strong, sharp, and structured Eu3+-related luminescence peaks at 576, 590, 611, 648, and 690 nm assigned to the 5D07F0-4 radiative transitions accompanied by a weaker, broad, blue luminescence at about 425 nm assigned to the silica glass matrix.
The PL excitation spectrum shows several sharp peaks assigned to the intra-configurational electronic transitions of Eu3+ optically active ions from the 7F0 ground level to the excited states: 5D4 (363 nm), 5GJ, 5L7 (372 nm–389 nm), 5L6 (392 nm). A weak shoulder at 397 nm indicated two different locations of the Eu3+ ions [11]. Previous investigations have shown that, in the glass-ceramic material, the Eu3+-ions are incorporated dominantly within the crystalline structure of the precipitated CaF2 nano-crystals (i.e., during the glass ceramization process); the substitution of Ca2+ ions by trivalent rare-earth cations leads to several different symmetries for the rare-earth sites [12,21].
The PL spectra recorded in the glass-ceramic additionally annealed in a reducing atmosphere show new features; the Eu3+-related luminescence peaks disappear and are replaced by a broad blue luminescence peaking at 425 nm accompanied by a weak and long tail in the visible region (Figure 4). The 425 nm luminescence band is similar to the one reported for Eu2+ doped CaF2 crystals [37]. Therefore, it was assigned to the Eu2+ ions that have replaced the Ca2+ ions in the cubic fluorite structure of the precipitated CaF2 nanocrystals [38]. This assumption is confirmed by the comparison between the corresponding excitation spectrum and the reported absorption spectrum [37], showing a typical "staircase" pattern between 310–425 nm, originating from transitions from the 4f7(8S7/2) ground state to the lowest crystal-field level of the 4f65d configuration [36] from which the Eu2+ radiative de-excitation is observed. The excitation spectra of the 425 nm or 490 nm (luminescence on the visible tail) are quite similar, showing a broad and structured band between 310 and 410 nm due to the crystalline field splitting. The similarity indicates that the origin of the long “tail” luminescence in the visible region is related to the transitions of Eu2+ in a crystalline environment, i.e., the calcium fluorite structure. The visible “tail” luminescence indicates a second type of Eu2+ ions in different locations/sites inside the CaF2 nanoparticles with slightly perturbed coordination, supposed to be associated with some structural defects. Hence, the luminescence measurements showed that the Eu3+ dopant ions are reduced to their bivalent state Eu2+ as a consequence of the processing in the reducing atmosphere being incorporated within the CaF2 nanocrystaline matrix; a very small Eu3+ fraction might still remain in the glass matrix [12].
The nature of the perturbation affecting the Eu2+ luminescence is supposed to be related to the Ca2+ ions substitution by the trivalent rare-earth cations and the involved compensation mechanism. In the CaF2 crystalline structure, the excess positive charge caused by the Eu3+ doping is compensated by the interstitial fluorine ions or by substitutional oxygen ions in a neighboring fluorine site [38,39]. The Eu2+ ions species are produced due to the Eu3+ to Eu2+ reduction reaction occurring during thermal processing using the hydrogen-based reducing atmosphere: Eu3+ ion gains an electron from the hydrogen that loses (or “donates”) that electron and transforms to Eu2+. At a close look, the Eu2+ luminescence band is slightly broader compared to the polycrystalline powder (Figure 3) and is accompanied by the long “tail” in the visible region. Hence, we suppose that interstitial fluorine ions and oxygen ions (from the silica matrix [12,34]) behave as perturbation factors of the Eu2+ luminescence, and the broadening effect is consistent with several sites present in the nanoparticles with different site symmetries. On the other hand, the influence of the nanosize effect on the broadening of the luminescence bands cannot be neglected [12].
The additional glass-ceramic processing in a reducing atmosphere influences the color impression of the samples, and Figure 5 shows the Commission Internationale de l’Eclairage (CIE) chromaticity diagram of the Eu2+-doped glass-ceramic sample. Under 345 nm excitation, the glass-ceramic sample shows a strong blue color associated with the Eu2+ blue luminescence with the coordinates x = 0.15 and y = 0.10. The corresponding photoluminescence quantum yield was about 0.76 and is higher than for Eu2+-doped CaF2 crystal of about 0.62 at a smaller dopant concentration, below 1% mol [37].

3.4. Electron Paramagnetic Resonance (EPR) Analysis

EPR spectroscopy is well-known as a powerful tool for detecting and investigating paramagnetic centers, such as Eu2+, as in the present material. Eu2+ has an S = 7/2 effective spin and two stable isotopes 151Eu and 153Eu, each with a nuclear spin number I = 5/2. In an ordered system, like a single crystal, Eu2+ would give rise to seven EPR lines, each split into six hyperfine lines due to the hyperfine interaction. The EPR spectra of Eu2+-doped crystals shows angularly dependent resonance positions, whereas, in polycrystalline media, all orientations are averaged out resulting in a complex spectrum.
The Q-band EPR spectrum recorded on Eu2+-doped glass-ceramics annealed in a reducing atmosphere shows a comprehensive signal, with an isotropic g-value of 1.9972 and a peak-to-peak linewidth of ~91 mT (Figure 6a); this signal was not observed in the glass-ceramics annealed in air (not shown). As the spectrum is similar to that recorded on Eu2+ doped CaF2 single crystal that shows fine structure centered at g = 1.99 [40], and PL measurements showed the Eu2+ luminescence in doped CaF2 crystals, we assign the EPR signal to the Eu2+ ions incorporated in the precipitated CaF2 nano-crystals in the glassy matrix. The spectrum does not present the fine structure due to the hyperfine interaction due to the high Eu2+ concentration (1%), which results in a strong spin–spin exchange interaction and nanocrystals random orientation, which results in the extreme broadening effect of the EPR spectrum [41]. Nevertheless, some low-intensity resonances depicted in the inset of Figure 6a indicate the fine structure of a Eu2+ ion. All the observations based on EPR spectroscopy show that, after subsequent annealing of the glass-ceramic in a reducing atmosphere, the EPR silent Eu3+ ions are reduced to EPR active Eu2+.
The X-band EPR measurements were also performed on the Eu2+-doped glass-ceramic annealed in a reducing atmosphere at temperatures ranging from 140 to 330 K (Figure 6b), and a new EPR resonance is observed at lower temperatures in the low field region. As this resonance signal was not observed on glass-ceramics annealed in air, we supposed it to be related to the Eu2+ too. The signal shifts towards g~2 with increasing temperature (the arrow from the Figure 6), consistent with a strong spin–lattice and spin–spin interaction. The temperature-shifting of the EPR signal is likely caused by the changes in the T1 relaxation time, which is dependent on the crystalline field of the CaF2 host material. Therefore, we suppose that a strong effect of the CaF2 crystalline field is exerted on the Eu2+ dopant ion, and the splitting of the Eu2+ ground state (8S7/2) arises from higher-order perturbations involving excited states [42]. The nature of the perturbations depends on the spin–orbit and spin–spin coupling, as well as on the symmetry and magnitude of the crystalline field potential.
To summarize, the EPR signal related to the Eu2+ ions detected only after the glass-ceramic is annealed in a reducing atmosphere. We assign the observed broad EPR signal to the Eu2+ ions incorporated in the CaF2 nanocrystals embedded in the glass matrix. The strong spin–spin exchange interaction and nanocrystals random orientation result in the extreme broadening of the EPR spectrum.

3.5. X-ray Photoelectron Spectroscopy (XPS) Analysis

In order to obtain specific information about the Eu ions species and the binding energies associated with different chemical bonds, we performed an XPS analysis of the Eu2+-doped SiO2-CaF2 glass-ceramic annealed in a reducing atmosphere (Figure 7).
The spectra showed the Ca-F and Si-O bonds associated with formation of CaF2 nanocrystals within the silica matrix, accompanied by much weaker C-C, C-O, and C-H bonds, due to the presence of calcination residue products [43] (Figure S2, supporting material). The XPS spectrum reveals interesting features in the 1120 to 1170 eV region expected for the Eu3d line. The spectrum is complex, composed of several convoluted peaks corresponding to the 3d5/2 and 3d3/2 Eu spin–orbit lines, separated by about 30 eV and with a peak area ratio of 3:2. For the Eu2+ ions, the multiplet structure is given by the two final states after photoionization, 5d04f7 and 5d14f6, where the satellites are relatively small, and therefore the main peaks can be revealed. As the 1125.8 eV peak energy is higher than expected for the Eu-O bond of about 1124–1125 eV, it was assigned to the Eu-F bonds [44], i.e., the Eu2+ incorporation within the CaF2 nanocrystals. The energy of the 1135.8 eV peak is slightly higher than that of the Eu2O3 oxide but smaller than for halides [45]. Therefore, it was assigned to the Eu3+ within an Eu-O bond, participating in a charge transfer process with surface contaminants. Hence, the Eu3+ ion species are present in the glass matrix, but their luminescence signal is weak, being covered by the much stronger Eu2+ luminescence (Figure 4). The quantification of the oxidation state of Eu is hard to do using the XPS technique (which is a thin-films investigation technique) because the Eu2+ ions are present in the nanocrystals, inside the volume of the glass-ceramic grain (according to the luminescence measurements), and therefore are more difficult to be observed by XPS. Hence, the ratio between Eu3+ and Eu2+ is overestimated (highly favorable to the Eu3+ ions), and, in this particular case, XPS provides only qualitative results.

3.6. Thermoluminescence (TL)

The thermoluminescence technique is a very sensitive and effective tool for investigating radiation effects in materials [46], particularly the new trapping levels induced by the RE3+-ions doping [47,48,49]. According to the basic model, charge carriers (electrons and holes) produced during irradiation are trapped in the band gap’s local energy levels (such as vacancies, interstitials, or impurities). During the heating, they are thermally released and recombine with carriers of the opposite sign, giving rise to TL [46]. In the present case, the effect of the reducing process of the europium ions (i.e., from Eu3+ to Eu2+) can be tracked using the thermoluminescence method too.
In Figure 8, the TL curves recorded on Eu2+-doped SiO2-CaF2 glass-ceramics annealed in a reducing atmosphere are presented and compared with that recorded in undoped glass-ceramic annealed in an air atmosphere as well as with CaF2 commercial crystalline powder. The TL curve recorded in Eu3+-doped SiO2-CaF2 glass-ceramics after the calcination in air showed a dominant high-temperature peak at 370 °C (not shown) assigned to the recombination of thermally released electrons from the Eu3+ electron traps [12].
However, new features are observed after subsequent calcination in a reducing atmosphere: the glass-ceramic samples show a single dominant TL peak centered at 85 °C as in the CaF2 powder or at 100 °C in ceramics [21] but accompanied by broader and unresolved peaks at higher temperatures above 150 °C. Analogous with the alkali halides crystals, where the glow peaks observed above room temperature were assigned to the F-type center recombination [50], we assign the 85 °C peak to the recombination of F-centres in the CaF2 crystalline matrix.
As the thermoluminescence spectra analysis of the Eu2+-doped CaF2 has shown the Eu2+ luminescence [21], this indicates the thermally activated recombination of F-type centers with Eu2+ stabilized hole centers followed by Eu2+ radiative emission. During the heating, the electrons are thermally released from the F-type centers and recombine with holes trapped as Eu3+/(Eu2+-hole) centers giving rise to the excited (Eu2+)* ions and radiative emission according to the reaction [51]:
(Eu2+-hole) + ékBT→ (Eu2+)*→Eu2+ + hν (425 nm)
Hence, the effect of Eu2+ ions relies on stabilization of hole centers in its neighborhood by comparison with the Eu3+ that behaves as a deep electron trap whose recombination is observed as a TL peak at high temperatures [12,49].
At a close look, it can be seen that the 85 °C glow peak is broader than in the CaF2 powder ceramic [21]. The effect was assigned to the calcium fluoride lattice distortion caused by some impurities or structural defects during the nanocrystals’ growth process in the glass environment, which is strongly influenced by the ionic environment and ionic impurities [52,53]. The high-temperature TL signal above 150 °C shown by the glass-ceramic samples (but not in the crystalline powder) was observed in the quartz [54]; therefore, it was assigned to the recombination of radiation induced defects in the silica glass matrix.
A final remark about the Eu2+ doping effect on the TL properties can be made. Compared to the Eu2+-doped BaCl2 nanoparticles [52], where the doping has improved the TL signal by more than one order of magnitude, in the case of Eu2+-doped SiO2-CaF2 glass-ceramic, we observed an opposite effect, as was observed in Eu2+-doped CaF2 ceramics [21]. Both Eu2+-doped SiO2-CaF2 glass-ceramics and ceramics [21] showed a strong diminishing of the TL signal with more than one order of magnitude, indicating an effect related to the CaF2 material itself and not its morphology. Hence, through the Eu2+-doping, the energy of the incident X-ray radiation is converted dominantly into Eu2+-luminescence instead of radiation defects formation, i.e., it has improved the luminescence properties and radiation hardness by inhibiting the formation of radiation defects, in particular F-centers.

4. Conclusions

The sol-gel approach has been used to prepare Eu2+-doped CaF2–SiO2 glass-ceramics in a two-step process: the controlled crystallization at higher temperatures of the Eu3+-doped xerogel precursor was followed by calcination in a reducing atmosphere, under a 5H2-95Ar gas flow. Structural characterization using X-ray diffraction has shown CaF2 nanocrystals of about 27 nm in size unaffected by the subsequent calcination. The photoluminescence spectra recorded under UV-light excitation of Eu2+-doped glass-ceramic showed the Eu2+ luminescence characteristic broad bands as a consequence of the Eu3+ → Eu2+ reduction. The 425 nm luminescence and the weak, visible tail were assigned to Eu2+ ions inside the CaF2 nanocrystals in substitutional and perturbed sites, respectively. The interstitial fluorine ions and/or substitutional oxygen ions required to compensate for the Eu3+ ions act as perturbation factors of the Eu2+ luminescence and the broadening effect compared to the crystals. The X-ray photoelectron and the EPR spectra confirmed the presence of the Eu2+ ions inside the CaF2 nanocrystals and strong spin–spin exchange interaction between Eu2+ ions, indicating a high (>1%) doping concentration. Thermoluminescence curves of the Eu2+-doped glass-ceramic showed a single dominant glow peak at 85 °C due to the recombination of the F-centers and Eu2+ related holes within the CaF2 nanocrystals. The Eu2+-doped SiO2-CaF2 glass-ceramic obtained using the sol-gel glass technology shows high luminescence efficiency (of about 76%) and X-ray radiation hardness, which can be successfully used as novel scintillator materials for radiation detection.
In conclusion, we demonstrated the possibility to produce Europium (II)-doped CaF2 nanocrystals embedded in a silica matrix by using controlled reduction of Eu(III)-doped SiO2-CaF2 glass-ceramics. The presented approach might be useful to obtain other new oxy-fluoride glass-ceramic materials doped with divalent ions such as Sm2+, Yb2+ for related applications: X-ray storage phosphor for digital imaging, persistent spectral hole burning for high-density optical memories, red broadband persistent luminescence, and white light sources.

Supplementary Materials

The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/nano12173016/s1, Figure S1: The EDX spectra analysis of the glass-ceramic sample; Figure S2: The XPS spectra were recorded on the glass-ceramic sample annealed in reducing atmosphere and shown in different energy regions.

Author Contributions

All the authors cooperated in the physical characterization and analysis of all the data: C.S. was involved in the sample preparation, XRD measurements, and pattern analysis; M.S. was responsible for the optical properties (photoluminescence, thermoluminescence, efficiency, and colorimetric analysis), experimental data analysis, and manuscript submission; A.-M.R. was responsible for the EPR measurements and their analysis; and all the authors contributed to the discussions, writing, and reviewed the manuscript. All authors have read and agreed to the published version of the manuscript.

Funding

The authors acknowledge the financial support from the Romanian Ministry of Research, Innovation, and Digitalization in the framework of the Core Program PN19-03 (contract No. 21 N/08 February 2019). The fee for open access publication was supported by the project 35PFE/2021, funded by the Romanian Ministry of Research, Innovation, and Digitization.

Data Availability Statement

The data presented in this study are available on a reasonable request from the corresponding author.

Acknowledgments

The authors acknowledge Elena Matei for the EDX analysis and Catalin Negrila for the XPS measurements and useful discussion.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Ming, W.; Jiang, Z.; Luo, G.; Xu, Y.; He, W.; Xie, Z.; Shen, D.; Li, L. Transparent Nano-Glass-Ceramic for Photonic Applications. Nanomaterials 2022, 12, 1491. [Google Scholar] [CrossRef] [PubMed]
  2. de Pablos-Martín, A.; Duran, A.; Pascual, M.J. Nanocrystallisation in oxyfluoride systems: Mechanisms of crystallisation and photonic properties Int. Mater. Rev. 2012, 57, 165–186. [Google Scholar] [CrossRef]
  3. Itoh, M.; Sakurai, T.; Yamakami, T.; Fu, J. Time-resolved luminescence study of CaF2:Eu2+ nanocrystals in glass-ceramics. J. Lumin. 2005, 112, 161–165. [Google Scholar] [CrossRef]
  4. Secu, M.; Secu, C.E.; Polosan, S.; Aldica, G.; Ghica, C. Crystallization and spectroscopic properties of Eu-doped CaF2 nanocrystals in transparent oxyfluoride glass-ceramics. J. Non-Cryst. Solids 2009, 355, 1869–1872. [Google Scholar] [CrossRef]
  5. Jiang, Y.; Zhang, P.; Wei, T.; Fan, J.; Jiang, B.; Mao, X.; Zhang, L. Europium doped transparent glass ceramics containing CaF2 micron-sized crystals: Structural and optical characterization. RSC Adv. 2016, 6, 55366–55373. [Google Scholar] [CrossRef]
  6. Kemere, M.; Rogulis, U.; Sperga, J. Luminescence and energy transfer in Dy3+/Eu3+ co-doped aluminosilicate oxyfluoride glasses and glass-ceramics J. Alloys Compd. 2018, 735, 1253–1261. [Google Scholar] [CrossRef]
  7. Hu, F.; Zhao, Z.; Yin, M. Structural characterization and temperature-dependent luminescence of CaF2:Tb3+/Eu3+ glass ceramics J. Rare Earths 2017, 6, 536–541. [Google Scholar] [CrossRef]
  8. Wang, C.; Chen, X.; Luo, X.; Zhao, J.; Qiao, X.; Liu, Y.; Fan, X.; Qian, G.; Zhang, X.; Han, G. Stabilization of divalent Eu2+ in fluorosilicate glass ceramics via lattice site substitution. RSC Adv. 2018, 8, 34536–34542. [Google Scholar] [CrossRef]
  9. Gorni, G.; Velázquez, J.J.; Mosa, J.; Balda, R.; Fernández, J.; Durán, A.; Castro, Y. Transparent Glass-Ceramics Produced by Sol-Gel: A Suitable Alternative for Photonic Materials. Materials 2018, 11, 212. [Google Scholar] [CrossRef]
  10. Secu, M.; Secu, C.; Bartha, C. Optical Properties of Transparent Rare-Earth Doped Sol-Gel Derived Nano-Glass Ceramics. Materials 2021, 14, 6871. [Google Scholar] [CrossRef]
  11. Pawlik, N.; Szpikowska-Sroka, B.; Goryczka, T.; Pisarski, W.A. Sol-Gel Glass-Ceramic Materials Containing CaF2:Eu3+ Fluoride Nanocrystals for Reddish-Orange Photoluminescence Applications. Appl. Sci. 2019, 9, 5490. [Google Scholar] [CrossRef]
  12. Secu, M.; Secu, C.E.; Ghica, C. Eu3+-doped CaF2 nanocrystals in sol–gel derived glass–ceramics. Opt. Mater. 2011, 33, 613–617. [Google Scholar] [CrossRef]
  13. Nogami, M.; Abe, Y. Enhanced emission from Eu2+ ions in sol-gel derived Al2O3–SiO2 glasses. Appl. Phys. Lett. 1996, 69, 3776–3778. [Google Scholar] [CrossRef]
  14. Nogami, M.; Abe, Y.; Hirao, K.; Cho, D.H. Room temperature persistent spectra hole burning of Sm2+-doped Silicate glasses prepared by the sol-gel process. Appl. Phys. Lett. 1995, 66, 2952–2954. [Google Scholar] [CrossRef]
  15. Poelman, D.; Smet, P.F. Europium-Doped Phosphors for Lighting: The Past, the Present and the Future. In International Workshop on Advanced Nanovision Science; Ghent University, Department of Solid State Sciences: Ghent, Belgium, 2011. [Google Scholar]
  16. Van den Eeckhout, K.; Smet, P.F.; Poelman, D. Persistent Luminescence in Eu2+-Doped Compounds: A Review. Materials 2010, 3, 2536–2566. [Google Scholar] [CrossRef]
  17. Li, G.; Tian, Y.; Zhao, Y.; Lin, J. Recent progress in luminescence tuning of Ce3+ and Eu2+-activated phosphors for pc-WLEDs. Chem. Soc. Rev. 2015, 44, 8688–8713. [Google Scholar] [CrossRef]
  18. Ye, W.; Liu, X.; Huang, Q.; Zhou, Z.; Hu, G. Co-precipitation synthesis and self-reduction of CaF2:Eu2+ nanoparticles using different surfactants. Mater. Res. Bull. 2016, 83, 428–433. [Google Scholar] [CrossRef]
  19. Anghel, S.; Golbert, S.; Meijerink, A.; Anja–Verena, M. Divalent Europium doped CaF2 and BaF2 nanocrystals from ionic liquids. J. Lumin. 2017, 189, 2–8. [Google Scholar] [CrossRef]
  20. Ye, W.; Huang, Q.; Jiao, X.; Liu, X.; Hu, G. Plasmon-enhanced fluorescence of CaF2:Eu2+ nanocrystals by Ag nanoparticles. J. Alloys Compd. 2017, 719, 159–170. [Google Scholar] [CrossRef]
  21. Nakamura, F.; Kato, T.; Okada, G.; Kawaguchi, N.; Fukuda, K.; Yanagida, T. Scintillation and dosimeter properties of CaF2 transparent ceramic doped with Eu2+. Ceram. Int. 2017, 43, 604–609. [Google Scholar] [CrossRef] [Green Version]
  22. Lan, Y.; Mei, B.; Li, W.; Xiong, F.; Song, J. Preparation and scintillation properties of Eu2+:CaF2 scintillation ceramics. J. Lumin. 2018, 208, 183–187. [Google Scholar] [CrossRef]
  23. McGregor, D.S. Materials for gamma-ray spectrometers: Inorganic scintillators. Annu. Rev. Mater. Res. 2018, 48, 245–277. [Google Scholar] [CrossRef]
  24. Zhou, L.; Chen, D.; Luo, W.; Wang, Y.; Yu, Y.; Liu, F. Transparent glass ceramic containing Er3+:CaF2 nano-crystals prepared by sol–gel method. Mater. Lett. 2007, 61, 3988–3990. [Google Scholar] [CrossRef]
  25. Krause, W.; Nolze, G. PowderCell a program for the representation and manipulation of crystal structures and calculation of the resulting X-ray patterns. J. Appl. Cryst. 1996, 29, 301–303. [Google Scholar] [CrossRef]
  26. Secu, C.E.; Predoi, D.; Secu, M.; Cernea, M.; Aldica, G. Structural investigations of sol–gel derived silicate gels using Eu3+ ion-probe luminescence. Opt. Mater. 2009, 31, 1745–1748. [Google Scholar] [CrossRef]
  27. Rüssel, C. Thermal decomposition of metal trifluoracetates. J. Non-Cryst. Solids 1993, 152, 161–166. [Google Scholar] [CrossRef]
  28. Secu, C.E.; Bartha, C.; Polosan, S.; Secu, M. Thermally activated conversion of a silicate gel to an oxyfluoride glass ceramic: Optical study using Eu3+ probe ion. J. Lumin. 2014, 146, 539–543. [Google Scholar] [CrossRef]
  29. Luo, W.; Wang, Y.; Cheng, Y.; Bao, F.; Zhou, L. Crystallization and structural evolution of SiO2-YF3 xerogel. Mater. Sci. Eng. B 2006, 127, 218–223. [Google Scholar] [CrossRef]
  30. Yu, Y.; Chen, D.; Wang, Y.; Luo, W.; Zheng, Y.; Cheng, Y.; Zhou, L. Structural evolution and its influence on luminescence of SiO2–SrF2–ErF3 glass ceramics prepared by sol–gel method. Mater. Chem. Phys. 2006, 100, 241–245. [Google Scholar] [CrossRef]
  31. Szpikowska-Sroka, B.; Zur, L.; Czoik, R.; Goryczka, T.; Swinarew, A.S.; Zadło, M.; Pisarski, W.A. Long-lived emission from Eu3+-doped PbF2 nanocrystals distributed into sol–gel silica glass. J. Sol-Gel Sci. Technol. 2013, 68, 278–283. [Google Scholar] [CrossRef] [Green Version]
  32. Del-Castillo, J.; Yanes, A.C.; Mendez-Ramos, J.; Tikhomirov, V.K.; Moshchalkov, V.V.; Rodrıguez, V.D. Sol–gel preparation and white up-conversion luminescence in rare-earth doped PbF2 nanocrystals dissolved in silica glass. J. Sol-Gel Sci. Technol. 2010, 53, 509–514. [Google Scholar] [CrossRef]
  33. Aguiar, H.; Serra, J.; Gonzalez, P.; Leon, B. Structural study of sol–gel silicate glasses by IR and Raman spectroscopies J. Non-Cryst. Solids 2009, 355, 475–480. [Google Scholar] [CrossRef]
  34. Wang, F.; Fan, X.; Pi, D.; Wang, M. Synthesis and luminescence behavior of Eu3+-doped CaF2 nanoparticles. Solid State Commun. 2005, 133, 775–779. [Google Scholar] [CrossRef]
  35. Labéguerie, J.; Gredin, P.; Mortier, M.; Patriarche, G.; de Kozak, A. Synthesis of Fluoride Nanoparticles in Non-Aqueous Nanoreactors. Luminescence Study of Eu3+: CaF2. Z. Anorg. Allg. Chem. 2006, 632, 1538–1543. [Google Scholar] [CrossRef]
  36. Dorenbos, P. Energy of the first 4f7→4f65d transition of Eu2+ in inorganic compounds. J. Lumin. 2003, 104, 239–260. [Google Scholar] [CrossRef]
  37. Kobaiashi, T.; Mroczkowski, S.J.; Owen, F.; Brixner, L. Fluorescence lifetime in Eu2+-doped chlorides and fluorides J. Lumin. 1980, 21, 247–257. [Google Scholar] [CrossRef]
  38. Dorenbos, P.; den Hartog, H.W. Space charges and dipoles in rare-earth-doped SrF2. Phys. Rev. B 1985, 31, 3932–3938. [Google Scholar] [CrossRef]
  39. Silversmith, A.J.; Radlinski, A.P. Zeeman spectroscopy of the G1 centre in CaF2:Eu3+. J. Phys. C Solid State Phys. 1985, 18, 4385. [Google Scholar] [CrossRef]
  40. Baker, J.M.; Bleaney, B.; Hayes, W. Paramagnetic resonance of S-state ions in calcium fluoride. Proc. R. Soc. Lond 1958, 247, 141–151. [Google Scholar]
  41. Antuzevics, A.; Kemere, M.; Krieke, G.; Ignatans, R. Electron paramagnetic resonance and photoluminescence investigation of europium local structure in oxyfluoride glass ceramics containing SrF2 nanocrystals. Opt. Mater. 2017, 72, 749–755. [Google Scholar] [CrossRef]
  42. Title, R.S. The cubic field splitting of the Eu2+ EPR spectrum in the alkaline earth flourides. Phys. Lett. 1963, 6, 13–14. [Google Scholar] [CrossRef]
  43. Secu, C.E.; Negrila, C.; Secu, M. Investigation of sol-gel derived BaCl2:Eu2+ luminescent nanophosphor and the corresponding PVP@BaCl2:Eu2+ polymer nanocomposite. J. Phys. D Appl. Phys. 2018, 51, 305302. [Google Scholar] [CrossRef]
  44. Vercaemst, R.; Poelman, D.; Fiermans, L.; Van Meirhaeghe, R.L.; Laflère, W.H.; Cardon, F. A detailed XPS study of the rare earth compounds EuS and EuF3. J. Electron Spectrosc. Relat. Phenom. 1995, 74, 45–56. [Google Scholar] [CrossRef]
  45. Mercier, F.; Alliot, C.; Bion, L.; Thromat, N.; Toulhoat, P. XPS study of Eu(III) coordination compounds: Core levels binding energies in solid mixed-oxo-compounds EumXxOy. J. Electron Spectrosc. Relat. Phenom 2006, 150, 21–26. [Google Scholar] [CrossRef]
  46. Bos, A.J.J. Thermoluminescence as a Research Tool to Investigate Luminescence Mechanisms. Materials 2017, 10, 1357. [Google Scholar] [CrossRef] [PubMed]
  47. Bos, A.J.J.; Dorenbos, P.; Bessière, A.; Viana, B. Lanthanide energy levels in YPO4. Radiat. Meas. 2008, 43, 222–226. [Google Scholar] [CrossRef]
  48. Krumpel, A.H.; van der Kolk, E.; Zeelenberg, D.; Bos, A.J.J.; Krämer, K.W.; Dorenbos, P. Lanthanide 4f-level location in lanthanide doped and cerium-lanthanide codoped NaLaF4 by photo- and thermoluminescence. J. Appl. Phys. 2008, 104, 073505. [Google Scholar] [CrossRef]
  49. Secu, C.E.; Secu, M.; Ghica, C.; Mihut, L. Rare-earth doped sol–gel derived oxyfluoride glass–ceramics: Structural and optical characterization. Opt. Mater. 2011, 33, 1770–1774. [Google Scholar] [CrossRef]
  50. Alvarez Rivas, J.L. Thermoluminescence and lattice defects in alkali halides. J. Phys. Colloq. 1980, 41, 353–358. [Google Scholar] [CrossRef]
  51. Secu, C.E.; Rostas, A.M. Investigations of BaCl2:Eu2+ nanophosphor using electron paramagnetic resonance, structural analysis and thermoluminescence. J. Alloys Compd. 2020, 815, 1524002. [Google Scholar] [CrossRef]
  52. Secu, M.; Secu, C.E. Processing and Optical Properties of Eu-Doped Chloroborate Glass-Ceramic. Crystals 2020, 10, 1101. [Google Scholar] [CrossRef]
  53. Schweizer, S.; Hobbs, L.W.; Secu, M.; Spaeth, J.-M.; Edgar, A.; Williams, G.V.M. Photostimulated luminescence in Eu-doped fluorochlorozirconate glass ceramics. Appl. Phys. Lett. 2003, 83, 449. [Google Scholar] [CrossRef]
  54. Wintle, A.G. Thermal Quenching of Thermoluminescence in Quartz Geophys. J. Int. 1975, 41, 107–113. [Google Scholar]
Figure 1. Thermal analysis results obtained on SiO2–CaF2 xerogel.
Figure 1. Thermal analysis results obtained on SiO2–CaF2 xerogel.
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Figure 2. The XRD patterns of the Eu3+-doped SiO2-CaF2 glass-ceramics annealed in air and additionally annealed in reducing atmosphere; the XRD pattern of CaF2 (PDF 35–0816) is also shown.
Figure 2. The XRD patterns of the Eu3+-doped SiO2-CaF2 glass-ceramics annealed in air and additionally annealed in reducing atmosphere; the XRD pattern of CaF2 (PDF 35–0816) is also shown.
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Figure 3. Transmission electron microscopy image of a Eu3+-doped SiO2-CaF2 glass-ceramic grain annealed in air (reproduced from Ref. [12]).
Figure 3. Transmission electron microscopy image of a Eu3+-doped SiO2-CaF2 glass-ceramic grain annealed in air (reproduced from Ref. [12]).
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Figure 4. (a) Normalized photoluminescence spectrum recorded under 392 nm excitation and excitation spectrum of the 615 nm luminescence recorded on Eu3+-doped SiO2-CaF2 glass-ceramics annealed in air; (b) photoluminescence spectrum recorded under 392 nm (or 365 nm) excitation and the excitation spectra of 420 and 490 nm luminescence recorded on the glass-ceramics annealed in reducing atmosphere. The photoluminescence spectrum of Eu2+-doped CaF2 crystalline powder is shown for comparison (dotted curve).
Figure 4. (a) Normalized photoluminescence spectrum recorded under 392 nm excitation and excitation spectrum of the 615 nm luminescence recorded on Eu3+-doped SiO2-CaF2 glass-ceramics annealed in air; (b) photoluminescence spectrum recorded under 392 nm (or 365 nm) excitation and the excitation spectra of 420 and 490 nm luminescence recorded on the glass-ceramics annealed in reducing atmosphere. The photoluminescence spectrum of Eu2+-doped CaF2 crystalline powder is shown for comparison (dotted curve).
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Figure 5. The chromaticity diagram of the Eu2+-doped SiO2-CaF2 glass-ceramic annealed in a reducing atmosphere showing chromaticity coordinates according to the Commission Internationale de l’Eclairage (CIE). The inset shows the image of the glass-ceramic powder annealed in a reducing atmosphere uniformly spread on the bottom of a Petri dish observed under a 345 nm UV light spot.
Figure 5. The chromaticity diagram of the Eu2+-doped SiO2-CaF2 glass-ceramic annealed in a reducing atmosphere showing chromaticity coordinates according to the Commission Internationale de l’Eclairage (CIE). The inset shows the image of the glass-ceramic powder annealed in a reducing atmosphere uniformly spread on the bottom of a Petri dish observed under a 345 nm UV light spot.
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Figure 6. Q-band EPR spectrum of the Eu2+-doped SiO2-CaF2 glass-ceramic annealed in a reducing atmosphere (a). The inset shows a magnification of the low-field EPR resonances. X-band EPR spectra of the Eu-doped glass-ceramic annealed in a reducing atmosphere at temperatures ranging from 130 to 330 K with 40 K steps (b).
Figure 6. Q-band EPR spectrum of the Eu2+-doped SiO2-CaF2 glass-ceramic annealed in a reducing atmosphere (a). The inset shows a magnification of the low-field EPR resonances. X-band EPR spectra of the Eu-doped glass-ceramic annealed in a reducing atmosphere at temperatures ranging from 130 to 330 K with 40 K steps (b).
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Figure 7. The XPS spectrum of the Eu2+-doped SiO2-CaF2 glass-ceramic annealed in a reducing atmosphere is shown in the Eu3d spectral line region and its deconvolution in the Eu 3d5/2 line region.
Figure 7. The XPS spectrum of the Eu2+-doped SiO2-CaF2 glass-ceramic annealed in a reducing atmosphere is shown in the Eu3d spectral line region and its deconvolution in the Eu 3d5/2 line region.
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Figure 8. Normalized thermoluminescence curves recorded in Eu3+-doped SiO2-CaF2 glass-ceramics annealed in reducing atmosphere compared to those recorded in un-doped glass-ceramics annealed in air and CaF2 commercial crystalline powder.
Figure 8. Normalized thermoluminescence curves recorded in Eu3+-doped SiO2-CaF2 glass-ceramics annealed in reducing atmosphere compared to those recorded in un-doped glass-ceramics annealed in air and CaF2 commercial crystalline powder.
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Secu, C.; Rostas, A.-M.; Secu, M. Europium (II)-Doped CaF2 Nanocrystals in Sol-Gel Derived Glass-Ceramic: Luminescence and EPR Spectroscopy Investigations. Nanomaterials 2022, 12, 3016. https://doi.org/10.3390/nano12173016

AMA Style

Secu C, Rostas A-M, Secu M. Europium (II)-Doped CaF2 Nanocrystals in Sol-Gel Derived Glass-Ceramic: Luminescence and EPR Spectroscopy Investigations. Nanomaterials. 2022; 12(17):3016. https://doi.org/10.3390/nano12173016

Chicago/Turabian Style

Secu, Corina, Arpad-Mihai Rostas, and Mihail Secu. 2022. "Europium (II)-Doped CaF2 Nanocrystals in Sol-Gel Derived Glass-Ceramic: Luminescence and EPR Spectroscopy Investigations" Nanomaterials 12, no. 17: 3016. https://doi.org/10.3390/nano12173016

APA Style

Secu, C., Rostas, A. -M., & Secu, M. (2022). Europium (II)-Doped CaF2 Nanocrystals in Sol-Gel Derived Glass-Ceramic: Luminescence and EPR Spectroscopy Investigations. Nanomaterials, 12(17), 3016. https://doi.org/10.3390/nano12173016

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