Introduction

Ytterbium (Yb3+)-doped glasses have been widely investigated for their potential in solid-state lasers1,2, downconversion3, upconversion4, light emitting diodes5, athermal lasers and more recently in solid-state laser induced cooling6. Basic requirements for laser cooling applications include materials of low phonon energy, low background absorption, high purity and photoluminescence quantum yield (PLQY)7.

Laser induced cooling based on anti-Stokes fluorescence was first proposed by Pringsheim8 and experimentally demonstrated for solids by Epstein et al. in Yb3+-doped ZBLANP glass6. Since 1995 laser cooling based on anti-Stokes fluorescence have been reported in a wide variety of low phonon energy host materials9,10,11,12 doped with Yb3+, Er3+ and Tm3+ ions12,13,14,15. Studies have been focused on the Yb3+ (4f13) ion as it has a very simple energy level structure consisting of only two manifolds, the ground (2F7/2) and excited (2F5/2) states which are well separated by about 10,000 cm−1. Yb3+-doped laser materials can be efficiently pumped by high-power commercially available diode lasers with wavelength in the range of 0.9–1.1 μm. Laser operation takes thus place in the 1.0 μm wavelength region close to the 1.06 μm wavelength laser line of Nd3+ ion. Efficient lasing is possible in Yb3+-doped materials because of small quantum defect (the energy difference between pump and lasing photons) which is not only the primary source of heating but also the source of anti-Stokes fluorescence for cooling1,9.

The PLQY of rare earth (RE)-doped solids is strongly influenced by the maximum phonon energy of the host, which determines the non-radiative relaxation rate. Fluoride glasses are thus favorable hosts for achieving higher PLQY owing to their low phonon energy (~580 cm−1, for the ZBLAN fluorozirconate glass) when compared with traditional oxide glasses (~1100 cm−1, for silicate glass). However, it is difficult to use them for practical applications due to their limited mechanical and chemical resistance. On the other hand, oxide glasses are usually preferred despite their higher phonon energy as they possess excellent chemical and mechanical properties. Oxyfluoride glasses based on heavy metal fluorides and silicates may surpass oxide and fluoride glasses by combining their advantageous properties such as low phonon energy, low melting point, high chemical durability and mechanical resistance, giving rise to unique materials with superior optical properties for a wide range of applications in photonics9,14,15,16,17,18. In addition, ultra-transparent glass-ceramics containing low phonon energy fluorite nanocrystals could also be produced under appropriate heat-treatment applied to as-made oxyfluoride glasses19. Oxyfluoride glasses and glass-ceramics may also be suitable for non-linear optical applications. As reported in the literature20, nano-glass-ceramics exhibiting a non-linear refractive index (n2 = 6.69 × 1014 cm2/W) about two times larger than that of their parent glasses (n2 = 3.23 × 1014 cm2/W) were obtained.

The motivation of our work is to develop low phonon energy oxyfluoride glasses for laser cooling applications. Glassy materials indeed exhibit various advantages over crystals such as ease of fabrication, capability of scaling-up and thus cost-effective production. Here, heavily Yb3+-doped oxyfluoride glasses belonging to the SiO2-Al2O3-PbF2-CdF2-YF3 vitreous system were prepared and characterized. Glass transition and crystallization temperatures, thermal stability against crystallization and thermal expansion coefficient were determined by thermal analysis. The PLQY was then evaluated for all the samples by using a pump wavelength at 920 nm from a Ti: sapphire laser and measuring the emission spectra with an integrating sphere coupled to an optical spectrum analyzer. The present study aimed at optimizing the Yb3+ ion concentration in order to obtain high PLQY and low background absorption. To the best of our knowledge, this is the first spectroscopic investigation report on these oxyfluoride glasses for laser cooling applications. The obtained results were compared with those reported on Yb3+: ZBLANP glass6 and Yb3+: YAG crystal12.

Theory

Laser cooling process in RE-doped host, which is based on anti-Stokes fluorescence, is illustrated in Fig. 1. The cooling efficiency of the sample can be described as:

Figure 1: Scheme of laser cooling cycle in Yb3+-doped systems.
figure 1

Here λp is the pump wavelength, λf is the fluorescence wavelength, Ep is the pump energy, Ef is the fluorescence energy, R is the reabsorption, and Wr is the radiative and Wnr is the non-radiative decay rates. If impurities (quencher: transition metal ions and other impurities) present in the glass matrix (host) absorb the pump laser, then luminescence quenching occurs, leading to heating of the sample.

where ηabs is the absorption efficiency which includes the resonant, αr and background absorption, αb.

is the external PLQY, where ηe is the fluorescence escape efficiency, which has been investigated in ref. 21. It also depends on the refractive index and shape of the sample. Wr and Wnr are the radiative and non-radiative decay rates, respectively. The fluorescence escape efficiency depends not only on the refractive index but also on the shape of the sample. As can be seen in Eq. (1), only RE-host combinations satisfying the inequality, WnrWr are suitable for laser cooling by anti-Stokes fluorescence. The mean fluorescence wavelength, λf can be calculated as:

where If(λ) is the measured emission spectrum without using an integrating sphere.

The external PLQY (ηext) can be expressed as the ratio of the number of emitted photons and the number of absorbed photons22:

where Nep is the number of emitted photons from the sample when the excitation beam is directed onto the sample, A is the absorption coefficient, Nip is the number of incident photons detected without the sample and Nepd is the number of emitted photons by the sample with the interaction of diffused light. In addition to Eq. (5) for evaluating the PLQY, we propose another relation to assess the PLQY.

By combining the above two relationships (6) and (7), we can get:

where Nap is the number of absorbed photons when the sample is excited directly with the laser in the integrating sphere, Nip is the number of incident photons collected without the sample in the integrating sphere and, Nsip is the number of scattered incident photons detected when the sample is inside the integrating sphere and the beam is directed on it.

Results and Discussion

Thermal and thermo-mechanical properties

The thermal and thermo-mechanical properties of the proposed cooling material are essential for investigating the integration of numerous optical parameters of an optical cooler. The DSC traces recorded on the 30SiO2-15Al2O3-(29-x)CdF2-22PbF2-4YF3-xYbF3 (mol%) glasses for various Yb3+ ion concentrations are shown in Fig. 2(a). The glass transition temperature (Tg, ±2 °C), the onset temperature of crystallization (Tx, ±2 °C) and peak crystallization temperature (Tp, ±1 °C) were determined from the thermograms as well as the corresponding glass thermal stability against crystallization criterion (ΔT = Tx − Tg, ±4 °C). Among the Yb3+-doped samples, a slight increase of their glass characteristic temperatures Tg, Tx and Tp is observed in Fig. 2(a,b) with increasing Yb3+ concentration. First, the increase of glass transition temperature (from 412 to 445 °C) with increasing Yb3+ content (from 0 to 20 mol%) shows here that the Yb3+ ions are well incorporated into the glass network. Whereas addition of RE ions like Yb3+ into a glassy material usually tends to decrease its stability by altering its network reticulation (and thus decreasing its Tg), it seems here that the addition of Yb3+ reinforces the glass network. The heavy level of doping attained (up to 20 mol%) supports this assumption. Further investigation is required to understand the structural role played by Yb3+ in such heavily doped glasses.

Figure 2
figure 2

(a) DSC traces of the undoped and Yb3+-doped 30SiO2-15Al2O3-(29-x)CdF2-22PbF2-4YF3-xYbF3 oxyfluoride glasses as a function of Yb3+ concentration (x). The thermograms were vertically shifted for better comparison. (b) Variation of Tg, Tx, Tp and ΔT of the samples under study as a function of Yb3+ concentration.

A progressive shifting towards higher temperature of the crystallization peak can be observed on the DSC traces (Fig. 2(a)) with increasing Yb3+ concentration. This slight increase of Tx and Tp can be directly correlated with the strengthening of the glass network after the replacement of Cd2+ cations by Yb3+ ions, as above mentioned. The shape of the crystallization peak also evolves with increasing Yb3+ concentration, as can be seen in Fig. 2(a). From the SYb05 to the SYb20 sample thermograms, the peak is broadening and clearly consists of two contributions: a sharp intense one at lower temperature, and a broad weak shoulder at higher temperature. It can be assumed that the first peak is related to the crystallization of β-PbF2 crystals, as already reported in refs 23, 24, 25 while the second contribution can be associated with the formation of new crystalline phase or even phase transformation. Further investigation focused on the crystallization kinetics and identification of the crystalline phase structure would be required to fully describe the crystallization process in these SiO2-Al2O3-CdF2-PbF2-YF3-YbF3 glasses. Nevertheless, it is worth mentioning that the undoped sample exhibits the highest temperatures of crystallization (both onset and peak) and the largest thermal stability against crystallization (ΔT = 69 °C, see Fig. 2(b)). In addition, one can see in Fig. 2(a) that its crystallization peak is weaker and flatter than those on the other DSC traces, indicating therefore that the undoped glass is less prone to crystallization. Such result was expected as it is well-known that addition of RE ions like Yb3+ into a glassy material tends to decrease its stability vs crystallization, as previously reported in many works in the literature23,24,26,27.

As above mentioned, the knowledge of the thermo-mechanical material properties such as thermal conductivity, specific heat capacity and thermal expansion coefficient (TEC) is crucial for a proper design of an optical cooler. The heat transfer rate within the cooled material is proportional to changes in temperature, thermal conductivity and heat capacity after excitation with a suitable laser28. Thermo-mechanical analysis (TMA) was performed on the samples SYb02 and SYb12. The TEC determined for these samples (in the temperature range of 100-350 °C) are 11.3x10−6/K and 13.7x10−6/K, respectively. The theoretical description of the TEC has been reported for Yb3+-doped phosphate laser glasses elsewhere29. The TEC values are higher than those reported for Li2O–Al2O3–SiO2 glasses (4.6–7.5 × 10−6/K)30, phosphate glass (LiPO3–Al(PO3)3–Ba(PO3)2–La2O3, 9.8 × 10−6/K)31, Yb3+:YAG crystal (8.06 × 10−6/K)32 but lower than that of ZBLAN fluorozirconate glass (16.4 × 10−6/K)33 and comparable to that of silicate laser glasses (12.7–13.4 × 10−6/K)34. The TEC values for the investigated glasses are between those of laser cooled materials such as Yb3+:YAG crystal32 and Yb3+:ZBLAN glass33.

Linear refractive index

The refractive indices of the glass samples were measured by the prism coupling technique with a resolution of ±0.001, and plotted in Fig. 3 as a function of wavelength and Yb3+ concentration. The values reported here were obtained for the transverse-electric (TE) mode of the incident laser radiation while no significant difference was observed in the transverse-magnetic (TM) mode, confirming the absence of birefringence, as expected in isotropic glass materials. First, one can observe in Fig. 3 a decrease of the refractive index with increasing the wavelength for each glass sample, showing thus their respective chromatic dispersion. The Sellmeier’s dispersion relation was used to fit the experimental data and facilitate their reading. Then, if we do not consider the undoped sample, one can observe that their refractive index decreases with increasing Yb3+ concentration. Such behavior is quite unusual. Indeed, glass doping with RE ions which are heavy elements compared to traditional components used to form glass (e.g. SiO2), generally results in increasing its refractive index. Here, the ytterbium fluoride (YbF3, molar mass = 230.04 g/mol) is incorporated into the glass by substituting for the cadmium fluoride, which is lighter (CdF2, molar mass = 150.41 g/mol), following the composition law 30SiO2-15Al2O3-(29-x)CdF2-22PbF2-4YF3-xYbF3 (mol%). Therefore, an increase of refractive index and density could be expected with increasing the Yb3+ concentration. However, while the density increase is observed with increasing Yb3+ concentration (as shown in Fig. S1) as expected, an opposite trend is observed for the refractive index in our glasses, as shown in Fig. 3. Interpreting the refractive index change of glasses as a function of their chemical composition is relatively complex. Indeed, it essentially depends on two factors, i.e. the glass molar volume (related to its density and molar mass) and the polarizability of its constituents. A tentative explanation can be as follows. First the high refractive index of these glasses is mainly governed by their large concentration of heavy metals with large electronic densities. Then, it is known that F anions possess a lower polarizability than O2− anions35. The progressive replacement of CdF2 by YbF3 in these glasses implies an increase of its fluorine content to the detriment of its oxygen content, as presented in the Table 1. This results then in a decrease of the glass average polarizability. Therefore the observed decrease in glass refractive index can be ascribed here to the dominant role played by its decreasing polarizability whereas its density, which increases with increasing Yb3+ concentration (see Fig. S1), has a lower impact. Last, one can also notice in Fig. 3 that refractive index was accurately measured at 972 nm for the undoped sample while no value was obtained by the prism couling method at that wavelength on the Yb3+-doped samples. We assume that it is related to the strong absorption of Yb3+ ion in this spectral region. Then, the refractive index of the undoped sample (as a function of wavelength) is comprised between those of the SYb08 and SYb12 samples, illustrating once again the complexity to represent its dependence on the glass chemical composition. Following the same reasoning as above, we would have indeed expected a higher refractive index for the undoped glass than for those doped with Yb3+ (because of a lower fluorine content). But it is clearly not the case here as one can see in Fig. 3. It can be assumed here that the density of the undoped glass, which is significantly lower than those of the Yb3+-doped glasses (Fig. S1), plays a more significant role. Further structural investigation is required to elucidate such behavior.

Figure 3: Measured linear refractive index (n) of the undoped and Yb3+-doped glasses as a function of wavelength.
figure 3

The data were fitted by using the Sellmeier’s dispersion formula.

Table 1 Elemental quantitative analysis (EPMA) of the undoped and Yb3+-doped samples compared with the theoretical values.

Electron probe micro analysis.

Electron probe micro analysis (EPMA) was carried out to identify and quantify the elemental composition of the prepared glasses. The experimental results along with the theoretical data are presented in Table 1. The synthesis process was performed at the same temperature (1100 °C) but with varying duration (1h30, 2h, 2h30, 3h, 3h30 and 4h) of the glass melting with increasing Yb3+ concentration. Note that the results presented in Table 1 are the mean value of five independent measurements on the same sample at different positions. It is worth mentioning that both theoretical and experimental F contents increase with increasing Yb3+ concentration whereas an opposite trend is observed in the case of the O content. To show the reproducibility of the synthesis process, the same glass (SYb02) was prepared three times by keeping all the conditions strictly identical (melting temperature and duration of glass melting are 1000 °C and 1 h, respectively) and the results are presented for the three samples in Table 2. The obtained maximum errors (%) in experimental results between the three samples when compared to theoretical values, indicate here an excellent repeatability of the sample preparation in the given conditions.

Table 2 Elemental quantitative analysis (EPMA) of three SYb02 samples prepared under identical conditions.

Absorption spectra

The UV-visible-near-infrared (NIR) absorption spectra of the undoped and SYb02 samples are presented in Fig. 4, showing a broad absorption band for the SYb02 sample centered at a wavelength of 975 nm which corresponds to the Yb3+:2F7/2 → 2F5/2 transition. The transmission spectra obtained for the other samples (see the supplementary information, Fig. S2) show very similar profiles with the same Yb3+ absorption band shape, except for its intensity which depends on the Yb3+ concentration, as plotted in the inset of Fig. 4. The inhomogeneously broadened absorption bands are due to the electronic transitions between the Stark sublevels of the ground (2F7/2) and the excited (2F5/2) levels as well as the strong electron-phonon interaction characteristic to the glassy host36. The quasi-linear variation of the integrated absorption band intensity observed with increasing Yb3+ concentration (inset of Fig. 4) indicates the presence of a similar local environment around the Yb3+ ions in all the investigated glasses.

Figure 4: UV-visible-NIR absorption spectra of the undoped and SYb02 samples.
figure 4

Inset shows a variation of the linear absorption coefficient, α (•, at 975 nm) and the integrated absorption band intensity (■, from 900 to 1100 nm) related with the Yb3+ band absorption as a function of its concentration in the SYb sample.

Photoluminescence quantum yield (PLQY)

The PLQY measurements were performed inside an integrating sphere coupled to an optical spectrum analyzer (OSA) with a multimode optical fiber and then determined using the method reported in refs 22, 25. The absolute photoluminescence spectra of the samples obtained under a laser excitation at 920 nm (510 mW of power), are presented as a function of their Yb3+ concentration in Fig. 5. As can be seen from Fig. 5, luminescence quenching is observed for Yb3+ concentration higher than 2 mol%, due to either an increase in the energy transfer or reabsorption by the Yb3+ ions. Reabsorption or radiation trapping effects are usual when dealing with Yb3+-doped glasses because of the overlap of their absorption and emission bands, directly related to the Yb3+ ion concentration, the sample thickness (2.3 mm for our samples) and the optical path length of the photons in the medium37,38.

Figure 5
figure 5

Absolute photoluminescence spectra under laser excitation at 920 nm (laser power of 510 mW) of the Yb3+-doped oxyfluoride glasses as a function of Yb3+ concentration (the sharp peak at 920 nm corresponds to the laser excitation line).

The absorption and emission spectra of the SYb02 sample (measured inside and outside the integrating sphere) are presented in Fig. 6. As can be seen in Fig. 6, reabsorption effect is observed even for the SYb02 sample and is more predominant for samples with higher Yb3+ concentration (as shown in the supplementary information, Fig. S3). The emission peak position shifts towards longer wavelength and broadens due to reabsorption. The reabsorption and luminescence quenching effects observed for all the Yb3+ concentrations are illustrated in Fig. 7(a,b). At lower concentrations, the interaction or radiation exchange between the Yb3+ ions is significantly reduced and may become negligible. In Fig. 7(a), the absorbed radiation from the pump laser is re-emitted in the form of luminescence (photons) without heat generation, resulting in higher luminescence intensity. At higher concentrations, the interaction between the Yb3+ ions becomes stronger and their energy exchange leads to a decrease in photoluminescence intensity due to non-radiative (phonons) emission resulting in luminescence quenching effect, as schematized in Fig. 7(b). This also induces the Yb3+ ions luminescence reabsorption by the Yb3+ neighboring ions, resulting in a redshift of the emission band.

Figure 6: Normalized absorption and emission bands of the SYb02 sample showing their overlapping responsible for the reabsorption effect.
figure 6

The emission spectra were measured outside and inside the integrating sphere under laser excitation at 920 nm. Outside the sphere: the sample was excited at a depth of 1 mm from the sample surface and the luminescence was collected with a multimode fiber and measured with an OSA. Inside the sphere: the sample was excited within the integrating sphere and the absolute luminescence was collected with a multimode fiber and measured with an OSA.

Figure 7
figure 7

Representation of the luminescence quenching effect of Yb3+ ions (•) in solids at (a) low and (b) high Yb3+ concentration. Excitation: solid red arrow, Emission: curved red arrow, and Non-radiative transition (heat generation): zigzag.

PLQY is evaluated by using both Eqs (2) and (5), giving similar values for each SYb sample as a function of Yb3+ concentration, as summarized in Table 1. The standard deviation of measurements is around ±0.11, which is typical of absolute PLQY measurements. Moreover, the acquisitions were repeated 5 times to ensure the consistency of the results. The highest PLQY value (0.99) was obtained for the SYb02 sample. Further increase of the Yb3+ concentration results in a PLQY decrease, owing to the concentration quenching effect. Then, the PLQY obtained for the SYb02 sample is comparable to that of Yb3+:YAG single crystal (containing 3 at.% of Yb3+)12 and Yb3+:ZBLANP glass6 in which optical cooling has been already demonstrated. It is worth mentioning that a high PLQY close to unity is one of the most important conditions in order to achieve a better cooling efficiency by removing successfully heat from the sample in every cooling cycle6. The background absorption coefficient (αb) of the samples, measured with a 1300 nm wavelength laser by the calorimetric method described in our earlier works12,25 is reported in Table 3. One observes a background absorption increase with increasing Yb3+ concentration.

Table 3 Photoluminescence quantum yield (PLQY) of the Yb3+-doped samples is determined by using the Eqs (2) and (5), pump wavelength (λP), limiting wavelength (λcutoff) which separates the integration of Nipj and Nepj (j = a,b and c), mean fluorescence wavelength (λf) which takes into account reabsorption, background absorption (αb) determined at 1300 nm laser by using the calorimetry method described in refs 12,25.

The mean fluorescence wavelength (λf) is calculated by using Eq. (4). The laser cooling/reduced heating can be expected when the samples are excited at or above λf6. As can be seen from Table 3, the λf value increases with increasing Yb3+ concentration due to reabsorption. The λf is found to be 1003(1) nm for the SYb02 sample which is larger than that reported for the Yb3+:ZBLANP (995 nm, 1 wt% of Yb3+)6. Hence, as the SYb02 sample exhibits high PLQY and low background absorption when compared with the other investigated samples, it appears to be the best candidate for laser cooling application besides serving as a reference sample for PLQY measurements in the near-infrared region.

Decay curves

The luminescence decay curves of the Yb3+:2F5/2 → 2F7/2 transition were measured by exciting with 940 nm wavelength laser and monitoring above the 975 nm wavelength emission, as shown in Fig. 8. The luminescence lifetime (τ) of the Yb3+:2F5/2 excited level was evaluated from a single exponential fit. It is observed that the τ of the Yb3+:2F5/2 excited state shortens from 1.52 to 0.19 ms in the investigated glasses when Yb3+ concentration increases from 2 mol% to 20 mol%. These results indicate that the decrease in PLQY with increasing Yb3+ concentration is not only due to reabsorption but also to concentration quenching. The quenching of lifetime may be either due to multiphonon relaxation, energy transfer among the Yb3+ ions (diffusion limited)39 or direct coupling with OH groups37. In the present study, since the amount of OH groups is expected to be relatively constant in all the samples, it is assumed that the most dominant mechanisms for lifetime quenching are the energy transfer among the Yb3+ ions, as well as the multiphonon relaxation. The longest lifetime measured here is 1.52 ms for the SYb02 sample, which is longer than that reported for the Yb3+:YAG crystal (1.1 ms, for a concentration of 2.5 at.% Yb3+)40 but shorter than that measured for the Yb3+:ZBLAN glass (1.82 ms, for a concentration of 2 mol% Yb3+)41. The high PLQY, which is a key parameter for laser cooling process, of the SYb02 sample with lower Yb3+ concentration (2 mol%) indicates its higher potential for laser cooling. Longer lifetime is not an obstacle for cooling, but it is not desirable, since it can slow down the cooling process.

Figure 8
figure 8

Decay curves for the Yb3+: 2F5/2 → 2F7/2 transition of the SYb samples as a function of Yb3+ concentration, under laser excitation at 940 nm.

Pump power dependence PLQY and lifetime studies

The pump power dependence of PLQY and lifetime measurements were performed on the Yb3+-doped glasses. Boconilli et. al. have reported on the pump power dependence studies of upconversion (UC, process consisting in the absorption of two or more photons of low energy followed by the emission of one photon of higher energy) PLQY in Er3+:β-NaYF4 nanocrystals by considering the effect of reabsorption for solar cell applications42. This is the first time to the best of our knowledge that the pump power dependence PLQY of Yb3+-doped glasses for laser cooling prospective is reported by considering. The PLQY (and the intensity of NIR emission as well) always follows a linear dependence with the pump power in our Yb3+-doped oxyfluoride glasses, as presented in Fig. 9. The PLQY was found to be as high as 0.99 for 510 mW of laser power measured at the entrance of the integrating sphere. Three regions are distinguished in Fig. 9, the first region for the low powers, the second one for intermediate powers and the third one for high excitation powers. The PLQY follows a progressive increase at low excitation powers whereas it remains unchanged at the intermediate excitation powers. This can be explained by the fact that there is no influence of the absorbed power by the Yb3+ ions which means that reabsorption may play a crucial role for this behavior providing a low fluorescence escape efficiency. At higher powers, the PLQY progressively increases due to the enhanced absorption of Yb3+ ions within the unit area for a fixed concentration. Moreover, the bleaching occurring at high pump powers can decrease significantly reabsorption, inducing further increase in PLQY43. The upconversion effects from the Tm3+ and Er3+ ions present as impurity traces (detailed discussion in the next section) at high pump powers may also cause a slight deviation from a straight line.

Figure 9
figure 9

Variation of PLQY with pump power for the 2 mol% Yb3+-doped glass.

The power dependence of lifetime for the Yb3+-doped glasses is shown in Fig. 10. As can be seen in Fig. 10, there is a small but consistent decrease of lifetime with increasing pump power, especially at higher Yb3+ concentration (20 mol%). This may be due to either a decrease in the lifetime and PLQY because of lower reabsorption due to bleaching effects43. The decrease in lifetime (Fig. 10) indicates that non-radiative and also upconversion processes should play an important role which means the non-radiative rate, Wnr, increases with increasing the Yb3+ concentration. The most important channels on the non-radiative rate increase are energy migration among Yb3+ ions, followed by transfer to impurity centers: trapping by defects such as OH radicals, radiation trapping of energy among Yb3+ ions, interaction between Yb3+ ions and the glassy host defects.

Figure 10
figure 10

Power dependence of lifetime for SYb samples with different Yb3+ concentrations.

Upconversion luminescence

The UC emission spectra of glasses recorded under laser excitation at 975 nm (80 mW power) are shown in Fig. 11 while a photograph of the UC luminescence from the SYb05 sample is shown in inset. It is clear that a higher UC intensity at 478 nm is obtained for the SYb05 sample than for the other samples. All the samples exhibit UC emissions at 478 nm (1G4 → 3H6) and 800 nm (3H4 → 3H6) originating from Tm3+ impurity as well as 410 nm (2H9/2 → 4I15/2), 539 nm (2H11/2, 2S3/2 → 4I15/2) and 647 nm (4F9/2 → 4I15/2) originating from Er3+ ions also present as an impurity. Those ions are excited thanks to energy transfer (Addition of Photons by Transfer of Energy: APTE effect) from the Yb3+ ions which act as a sensitizer44. It was evidenced that the APTE effect is 105 times more efficient than the cooperative luminescence which is usual in Yb3+-doped samples at high concentrations for the same Yb3+-Yb3+ distances45,46. Due to this reason no cooperative luminescence was observed in these glasses even at high Yb3+ concentration. The pump power dependence of the UC luminescence is shown in Fig. S4. It is worth mentioning that no UC emission was observed from the Yb3+ free sample (as shown in Fig. S5). Therefore, it is clear that these Tm3+ and Er3+ traces (contents of respectively less than 10 and 8 ppm according to the certificate of analysis provided by the chemical supplier) originate from the YbF3 starting powder, in spite of its relatively high purity (99.99%). Complete separation of RE ions during their manufacturing process to obtain ultra-high purity raw materials is indeed a well-known issue in the industry.

Figure 11: UC emission spectra of Er3+ and Tm3+ ions in the SYb samples under laser excitation at 975 nm with 80 mW laser power as a function of Yb3+ concentration.
figure 11

Inset is a picture of the bright blue UC emission of the SYb05 sample coming from the presence of Tm3+ ions as an impurity.

Conclusion

Heavily Yb3+-doped 30SiO2-15Al2O3-(29-x)CdF2-22PbF2-4YF3-xYbF3 (where x = 2, 5, 8, 12, 16 and 20 mol%) oxyfluoride glasses have been fabricated and characterized from a thermal and spectroscopic point of view. Their glass transition and crystallization temperatures as well as thermal expansion coefficient were determined by thermal analysis. The measured linear refractive index of the SYb samples varies from 1.780 to 1.730 at 532 nm and decreases with increasing Yb3+ concentration. Luminescence intensity at 1020 nm under laser excitation at 920 nm decreases with increasing the Yb3+ concentration. The highest photoluminescence quantum yield (0.99, near unity) was obtained for the 2 mol% Yb3+-doped sample and was then found to decrease when increasing the Yb3+ concentration. The PLQY increases with increase in the pump power up to 510 mW, the limit of the laser used in this work. The mean fluorescence wavelength was evaluated from the emission spectrum and reported to be 1003(1) nm for the 2 mol% Yb3+: glass which increases with increasing Yb3+ ion concentration. Pump power dependence studies have revealed a linear increase in the PLQY and a decrease in the lifetime with increasing the pump power. The lifetime of the 2F5/2 level shortens from 1.52 ms to 0.19 ms with increasing the Yb3+ concentration.

The 2 mol% Yb3+-doped oxyfluoride glass with its high PLQY, its low maximum phonon energy and low background absorption is the most promising candidate for laser cooling and solid-state laser applications besides serving as a reference to calibrate the instruments for PLQY measurements. Future works will focus on one hand on the fabrication of glasses of ultra-high purity, which is a required condition to achieve optical cooling and; on the other hand, on the preparation of ultra-transparent nano-glass-ceramics in a similar vitreous system with the aim to further enhance the photoluminescence quantum yield, to decrease the background absorption and in fine to demonstrate laser cooling in this material.

Methods

Oxyfluoride glasses with chemical composition 30SiO2-15Al2O3-(29-x)CdF2-22PbF2-4YF3-xYbF3 (mol%), where x = 2, 5, 8, 12, 16 and 20 were prepared by the conventional melt-quenching technique. The glass samples were labeled as SYb02, SYb05, SYb08, SYb12, SYb16 and SYb20, respectively. High purity commercial starting materials (Aldrich, 99.99%) were thoroughly mixed in an agate mortar and then loaded into a platinum crucible. The powders were then melted and homogenized at 1100 °C for different durations (1h30, 2h, 2h30, 3h, 3h30 and 4h with increasing Yb3+ concentration respectively) in a muffle furnace under ambient atmosphere in the covered crucible. The glass melt was then casted into a stainless steel mold preheated close to the glass transition temperature (Tg), subsequently annealed at the same temperature for 5 h and slowly cooled to room temperature to remove any residual internal stress. The glass samples were finally polished to optical quality for further characterization.

The density of the samples was measured by using a Mettler Toledo XSE204 densimeter with a resolution of ±0.001 g/cm3. The linear refractive index of the samples was measured by employing the prism coupling technique (Metricon 2010) at different wavelengths, 532, 633, 972, 1308 and 1538 nm. Differential scanning calorimetric (DSC) measurements were performed by using a Netzsch DSC Pegasus 404F3 apparatus on glass pieces in PtRh pans at a heating rate of 10 °C/min. The thermal expansion coefficient (TEC) was measured by using a Netzsch TMA 402F1 Hyperion thermo-mechanical analyzer apparatus on glass rods of 5 mm length and 10 mm diameter at a heating rate of 5 °C/min up to the glass softening point with a load of 0.02 N. The TEC of the sample was then determined in the temperature range from 100 to 300 °C. UV-visible-near infrared transmission spectra were recorded on a Cary 5000 (Varian) double-beam spectrophotometer. The photoluminescence quantum yield (PLQY) of the samples (10 mm × 2 mm × 2 mm) was measured by pumping at a wavelength of 920 nm with a Ti:sapphire laser, collecting the emitted light from an integrating sphere (2″) (Thorlabs IS200) and coupling it through a multimode optical fiber to an optical spectrum analyzer (OSA) operating in the wavelength range of 800–1600 nm. The photoluminescence spectra were also measured outside the integrating sphere under 920 nm wavelength laser excitation. The upconversion luminescence spectra were recorded using a Nanolog (Horiba Jobin Yvon) fluorimeter equipped with a double monochromator and a photomultiplier tube sensitive from 250 to 825 nm. A laser diode operating at 975 nm coupled with a standard single-mode pigtailed fiber was used to excite the samples after beam collimation and focusing on the sample surface with a lens (f = 50 mm). Decay curves were recorded with a resolution of 10 μs by using a photodiode (Thorlabs SM05PD1B). The signal was amplified by a bench top transimpedance amplifier (Thorlabs PDA200C) and read with a digital storage oscilloscope (Tektronix TDS2012CB 100MHZ 2GS/s).

The pump power dependence PLQY studies were performed by exciting the samples with a 920 nm wavelength laser from a Ti: Sapphire while the output power was maintained constant by using a Glan-Thompson polarizer. Part of the laser power was tapped by a glass slide and monitored with a Keithley 6487 Picoammeter. The transmitted beam was focused at the entrance port of the integrating sphere and directed to the center of the sphere where the sample was situated. The diffused light from the sphere walls was collected by a multimode fiber of 200 μm diameter and detected with an Ando AQ6317B optical spectrum analyzer. The data was collected and processed in a computer which measures 50 spectra, while normalizing them to the tapped optical power. All the measurements were performed at room temperature.

Additional Information

How to cite this article: Krishnaiah, K. V. et al. Development of ytterbium-doped oxyfluoride glasses for laser cooling applications. Sci. Rep. 6, 21905; doi: 10.1038/srep21905 (2016).