The Yb³⁺ dopants in YAG replace Y³⁺ ions and occupy the site symmetry D₂, which results in nine non-vanished pure imaginary intensity parameters with (k, t, p) = (2,3,2), (4,3,2), (4,5,4), (6,5,4), (4,5,2), (6,5,2), (6,7,6), (6,7,4), and (6,7,2), which are independent variables to be fitted, and the estimated initial values are shown as in Table 1.

Table 1.

Table 1.

Table 1. Initial and fitted parameters of in 10−13 m, Huang–Rhys factor s, FWHM in unit nm, and manual adjusted C in 10−18 s. . Parameters Initial values Fitted values with τ = 643 μs Fitted values with τ = 950 μs –1.769 –8.748 5.254 –1.988 –4.923 4.570 –0. 368 –0.816 0.302 –0. 998 0.367 0.586 –0. 637 –19.735 16.339 – 1.728 –1.348 0.940 0. 17 –16.54 13.315 0. 533 0.151 1.355 0. 156 –6.601 5.824 s1 0.32 0.35 0.33 s2 0.12 0.31 0.25 w1 0.75 0.65 0.75 w2 0.42 0.52 0.53 w3 2.2 2.20 2.23 1.1 0.687 0.341 C / 6.17 17.66

Table 1. Initial and fitted parameters of in 10−13 m, Huang–Rhys factor s, FWHM in unit nm, and manual adjusted C in 10−18 s. .

The crystal field energy levels of Yb³⁺ in YAG have been evaluated in Ref. [11], which is denoted as |J, Γ_i〉(r), where Γ_i is point group irreducible representation, r represents the multiplicity of |J, Γ_i〉. |J, Γ_i〉(r) refers to the dominant component of the corresponding wavefunctions. For convenience, the energy levels of Yb:YAG are labeled as E_i (i = 1, 2, 3, 4, 5, 6 and 7) form low to high energy, which is 0, 564, 606, 787, 10329, 10629, and 10829 in unit cm⁻¹ (wavenumber). The calculated photoluminescence emission intensity of Yb³⁺, including electric and magnetic dipole transitions, can be expressed as^[9]

In order to eliminate the arbitrariness resulting from measurement, the transition intensity and energy life time of |5/2, Γ₁〉 (1) with E₁ are fitted at the same time to the following equation:^[9]

Three pure electron state transitions, which correspond to the emission peaks at 1023.5 nm, 1028 nm, and 1046.1 nm, and three vibronic coupling transitions peaking at 1021.4 nm and 1028.28 nm, which mean that Yb³⁺ absorbs a phonon of 22 cm⁻¹ and releases a phonon of 3.0 cm⁻¹, were used to fit the emission spectrum of Yb:YAG at 8-K temperature.

Fifteen variables, including nine transition intensity parameters , two Huang–Rhys factors s, three FWHMs w, and one , are fitted to the emission spectrum and decay time of Yb:YAG. The initial values of are evaluated with point charge model (PCM). The line profile function ϕ is Lorentz function, and the iteration method is the Levenberg–Marquardt method. After 20 iterations, φ = 0.0086, relative residual R is 12.1%, and the calculated decay time is 638 μs, which is very close to experimental value 643 μs. The obtained parameters are listed in Table 1.

Due to the high dopant concentration, the fluorescence quenching is obvious. According to Ref. [12], the decay time of Yb³⁺:YAG is 950 μs, and its temperature dependence is not obvious. So the decay time of 950 μs is also used to fit the transition intensity parameters of Yb:YAG again. After 20 iterations, R reaches 12.1%, and the calculated decay time of E₅ is 953 μs. Next, the obtained are fixed, and the Huang–Rhys factor, FHWM and are fitted again. The finally obtained values are listed in Table 2, the calculated and experimental emission spectra are shown in Fig. 2. It can be seen that the longer the decay time, generally the smaller the transition intensity parameters are, which results from the case where the decay time is inversely proportional to transition probability A_IF, and if magnetic contribution is omitted. Omitting their signs, the ratios of ((k, t, p) = (2,3,2), (4,3,2), (4,5,4), (6,5,4), (4,5,2), (6,5,2), (6,7,6), (6,7,4), (6,7,2)) obtained by fitting with the decay times of 950 μs and 643 μs, are 0.60, 0.93, 0.37, 1.60, 0.83, 0.70, 0.81, 8.97, 0.88, respectively, most of which are close to , which indicates that are approximately inversely proportional to the square root of the decay time, and the precise decay time is important for determining .

Fig. 2.

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	Fig. 2. (color online) Calculated and experimental emission spectra of (10 at.%) Yb:YAG at 8 K.

Table 2.

Table 2.

Table 2. Values of transition probability A, line strength S, fluorescence branch ratio β of Yb3+:YAG at 8 K. . Transition λ/nm Aed/(1/s) Sed/10−0 cm2 Amd/(1/s) Smd/10−20 cm2 A/(1/s) β/% E5 → E1 968 457.2 0.20 0 0 457.4 43.6 E5 → E2 1023.5 57.4 0.03 5.1 2.5 × 10−3 62.5 6.0 E5 + phonon of 22 cm−1 → E2 1021.2 26.7 0.014 2.4 1.0 × 10−3 29.0 2.8 E5 → E3 1028 302.0 0.16 2.9 1.4 × 10−3 305.0 29.0 E5 → E3 + phonon of 3.0 cm−1 1028.3 175.0 0.09 1.7 8.2 × 10−4 176.6 16.8 E5 → E4 1046 19.4 0.01 0.2 8.2 × 10−5 19.5 1.9

Table 2. Values of transition probability A, line strength S, fluorescence branch ratio β of Yb3+:YAG at 8 K. .

The transition probabilities and line strengths of Yb:YAG are listed in Table 2. It can be seen that magnetic dipole transitions are very weak in all of transitions, its total transition probability is 12.3/s, the total electric dipole ratio reaches up to 1050/s, and the ratio of magnetic transition is about 1%. It is surprised that the branch ratio of E₅→ E₁ is very large, which is 43.6%, although it is very weak in the observed emission spectrum. The transitions of E₅→ E₃ and phonon assisted transition E₅→ E₃ + phonon of 3 cm⁻¹with Huang–Rhys factor 0.25, which is usually used as laser channel, account for 29.0% and 16.8%, and their sum is about 45.8%, respectively. So 45.8% should be the possible highest efficiency of a diode-pumped solid state laser by using Yb³⁺:YAG as a gain medium. On the other hand, during the procedure of E₅ + phonon of 22 cm⁻¹ with Huang–Rhys factor 0.33 → E₂, Yb³⁺:YAG can absorb a phonon and emit a higher-energy photon, which will reduce the thermal load during laser operation and result in its good thermal properties and high efficiency.

The emission spectrum of (10 at.%) Yb:YAG excited by the light of 914.8 nm is shown in Fig. 3, which can be fitted by seven Lorentz functions, and their FWHMs, centers and areas are shown in Table 3.

Fig. 3.

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	Fig. 3. (color online) Emission spectra of (10 at.%) Yb:YAG at 300 K (λex = 914.8 nm).

Table 3.

Table 3.

Table 3. Fitted results of the room temperature emission spectra of (10 at.%) Yb:YAG with Lorentz profile. . Center/nm FWHM/nm Area/a.u.⋅nm 968.1 4.46 85401 981.3 7.85 32021 1000.8 19.4 223355 1006.5 11.1 112526 1024.2 6.5 494926 1029.1 4.7 1.1 × 106 1047.4 9.4 176155

Table 3. Fitted results of the room temperature emission spectra of (10 at.%) Yb:YAG with Lorentz profile. .

The emission band with peak 981 nm should be from the vibronic band of E₅ → E₁ of Yb:YAG, and has the same initial state as the emission band with peak 968.1 nm. When the temperature increases, the lattice vibration intensifies, and the corresponding phonon energy should increase. So it is suggested that the emission bands of 1000.8 nm and 1006.5 nm are from the vibronic bands of E₅ → E₂, which means that the transition with one-phonon assisted transition at low temperature has turned into two-phonon assisted transitions with energies of 172 cm⁻¹ and 228 cm⁻¹, respectively.

Due to the strong re-absorption near 968 nm, the emission spectrum as shown in Fig. 4, in which the emission band of 968 nm is stripped and not included in fitting. No obvious dependence of decay time on temperature is observed, and it is reasonable to assume that the transition probability of Yb:YAG nearly keeps constant during temperature changing from the low temperature to room temperature. Then values obtained from the emission spectrum of 8 K are used and fixed, and Huang–Rhys factor, FWHM and are fitted to its emission spectrum of 300 K again. The 14 iterations are performed and final R is 11.7%, the decay time of E₂ is calculated to be 952 μs and close to the experimental value 950 μs, and the values of s₁ and s₂, which correspond to the phonon assisted transitions of E₅ → E₂ and E₃, are 0.129 and 0.006, respectively. The other fitted parameters are listed in Table 4. The fitted curve is shown is Fig. 4, the consistency between the calculated and experimental curves near 100 nm is not so good, which may be due to the fact that only two-phonon assisted transition procedures are considered, more-phonon assisted transitions at room temperature are needed in order to reach good consistency. But the emission bands near 1000 nm are weak, and the present difference between calculated and experimental values is not dominant, so no more-phonon assisted transitions are considered and incorporated into the fitting.

Fig. 4.

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	Fig. 4. (color online) Fitted and experimental emission spectra of (10 at.%) Yb:YAG at 300 K (λex = 914.8 nm).

Table 4.

Table 4.

Table 4. Parameters fitting the emission spectrum of (10 at.%) Yb:YAG at room temperature. . Initial value Final value s1 0.1 0.1291 s2 0.02 0.0063 w1/nm 1.88 2.05 w2/nm 3.24 2.94 w3/nm 1.63 1.64 1.1 0.295654 C/10−18 s 1.766 × 10−17

Table 4. Parameters fitting the emission spectrum of (10 at.%) Yb:YAG at room temperature. .

Table 5.

Table 5.

Table 5. Values of transition probability A, line strength S, fluorescence branch ratio β of Yb3+:YAG at 300 K. . Transition λ/nm Aed/(1/s) Sed/10−20 cm2 Amd/(1/s) Smd/10−20 cm2 A/(1/s) β/% E5 → E1 968 457.2 0.02 0 0 457.2 43.5 E5 + phonon of 172 cm−1 → E2 1000.2 15.0 7.2 × 10−3 1.3 6.0 × 10−4 16.4 1.6 E5 + phonon of 228 cm−1 → E2 1005.8 16.4 8 × 10−3 1.5 6.7 × 10−4 17.8 1.7 E5 → E2 1023.5 66.4 0.03 5.9 2.8 × 10−3 72.3 6.9 E5 → E3 1029.1 327.1 0.22 3.1 1.5 × 10−3 330.2 31.4 E5 → E3 + phonon of 3.0 cm−1 1029.4 135.6 0.07 1.3 6.4 × 10−4 136.9 13.0 E5 → E4 1047.4 19.4 0.01 0.2 8.2 × 10−5 19.5 1.9

Table 5. Values of transition probability A, line strength S, fluorescence branch ratio β of Yb3+:YAG at 300 K. .

Emission cross section is a gain ability parameter of a laser medium and can be used to evaluate its laser performance directly. Because there exists an obvious concentration quenching in (10 at.%) Yb³⁺:YAG, so its emission cross section is calculated by fitted with the decay time 950 μs. The emission cross section of Yb³⁺ is calculated by^[10]

As a comparison, the emission cross section of Yb³⁺:YAG is calculated by Fuchtbauer–Ladenburg (F–L) equation^[7] 6 where τ_rad is the decay time, and profile function ϕ′(λ) is calculated from emission spectrum I(λ) as follows:

The emission cross sections at 8 K calculated by Eqs. (4) and (6) are shown in Fig. 5 and Table 6. It can be seen that emission cross section from E₅ → E₁, with a peak value of 0.07 × 10⁻²⁰ cm² at 968 nm, calculated by the F–L formula is very close to zero due to the strong re-absorption of Yb³⁺, but the corresponding value calculated by Eq. (4) with intensity parameters is 5.07 × 10⁻²⁰ cm². The emission cross sections obtained with the F–L formula at 1021.2 nm, 1023.5 nm, 1028 nm, 1028.3 nm, 1046 nm, which correspond to the transitions E₅ + phonon → E₂, E₅ → E₂, E₅ → E₃, E₅ → E₃ + phonon, and E₅ → E₄, are 1.29, 3.06, 22.09, 21.57, 0.36 in 10⁻²⁰ cm², and the corresponding values calculated by intensity parameters and profile functions are 0.81,1.61, 12.04, 11.95, 0.18 in 10⁻²⁰ cm². It can be seen that the later values are much less than the former values. According to the emission cross sections of Yb³⁺:YAG at cryogenic temperatures,^[7] the emission cross sections are about 11 × 10⁻²⁰ cm² at 80 K, which is close to 12.04 × 10⁻²⁰ cm² of 1028 nm, and 12.04 × 10⁻²⁰ cm² of 1028.3 10⁻²⁰ cm² at 8 K, respectively, which indicates that our calculated cross sections are reasonable. The overrated cross sections through F–L formula result from the case where the strong reabsorption of E₁ → E₅ causes the ∫I(λ)dλ to be underrated, and profile value is overrated in the wavelength at which there exists no reabsorption.

Fig. 5.

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	Fig. 5. (color online) Emission cross sections of Yb:YAG, calculated by intensity parameters (a) and F–L formula (b) at 8 K.

Table 6.

Table 6.

Table 6. Values of emission cross section σem (in 10−20 cm2) of Yb3+:YAG, calculated with and F–L formula at 8 K and 300 K. . Transition at 8 K at 300 K λ/nm with with F–L λ/nm with with F–L E5 → E1 968 5.07 0.07 968.1 1.16 0.24 E5 + phonona → E2 1021.4 0.81 1.29 1000.8 0.16 0.24 E5 + phononb → E2 / / / 1006.5 0.18 0.32 E5 → E2 1023.5 1.61 3.05 1024.1 1.03 1.72 E5 → E3 1028 12.04 22.09 1029.1 2.34 3.78 E5 → E3 + phononc 1028.3 11.95 21.57 1029.4 2.33 3.74 E5 → E4, 1046.1 0.18 0.36 1047.4 0.25 0.38 a Phonon energies are 22 cm−1 at 8 K and 228 cm−1 at 300 K b 172 cm−1 at 300 K, and c 3 cm−1 at 8 K and 300 K.

Table 6. Values of emission cross section σem (in 10−20 cm2) of Yb3+:YAG, calculated with and F–L formula at 8 K and 300 K. .

The emission cross sections at 300 K are also calculated by and F–L formula is shown as in Fig. 6. The emission spectra are broadened as sample temperature increases. Then the profile function peak values decrease, and the cross section peak values also decrease. For example, the fitted FWHMs of E₅ → E₂, E₃ are 0.61 nm and 0.52 nm at 8 K and 2.05 nm and 2.94 nm at 300 K, and the cross sections calculated with are 1.61 and 12.04 in 10⁻²⁰ cm² at 8 K, and 1.03 and 2.33 in 10⁻²⁰ cm² at 300 K, respectively.

Fig. 6.

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	Fig. 6. (color online) Emission cross sections of Yb:YAG at 300 K.

According to Judd–Ofelt triple parameter intensity formula, if the crystal field energy level splitting is omitted, the dipole transition line strength of ²F_5/2 →² F_7/2 can be calculated by

In summary, the emission spectrum of Yb³⁺:YAG at 8 K consists of four pure electron state transitions and two-phonon assisted transitions, one vibronic transition releases a phonon, and the other vibronic transition absorbs a phonon in the frame of the single frequency approximation. In the emission spectrum at 300 K, there exist one vibronic transition releasing a phonon, and two vibronic transitions absorbing a phonon. The optical transition procedure absorbing phonon can reduce the thermal load of Yb³⁺:YAG and improve its thermal management. Emission cross sections determined by F–L formula are remarkably different from those calculated by , F–L formula underrates the emission cross sections in a reabsorption wavelength region, and overrates emission cross sections in other wavelength regions.