Journal of Synthetic Crystals ›› 2026, Vol. 55 ›› Issue (6): 910-929.DOI: 10.16553/j.cnki.issn1000-985x.2026.0037
• Research Articles • Previous Articles Next Articles
SONG Qingsong1,2(
), LIU Jian2, ZHANG Fan1, ZHANG Chaoyi1,3, WANG Wudi1, CAO Xiao1, QIAN Xinyu1, TANG Huili1, WANG Qingguo1, ZHANG Chenbo1, LIU Bo1, XU Xiaodong2, XU Jun1(
)
Received:2026-03-09
Online:2026-06-20
Published:2026-07-07
Contact:
XU Jun
CLC Number:
SONG Qingsong, LIU Jian, ZHANG Fan, ZHANG Chaoyi, WANG Wudi, CAO Xiao, QIAN Xinyu, TANG Huili, WANG Qingguo, ZHANG Chenbo, LIU Bo, XU Xiaodong, XU Jun. Growth, Quenching Mechanism, and Luminescent Properties of Mn4+∶K2Ge4O9 Single Crystals[J]. Journal of Synthetic Crystals, 2026, 55(6): 910-929.
Fig.2 Physical photo of the Mn∶KGO sample prepared during the exploration stage and its luminescence image under ultraviolet light. (a) Samples formed by the molten drops from the feed rods in the optical floating zone furnace (transparent and orange parts); (b) transparent sample obtained from the molten drops via the floating zone method; (c) luminescence images of the transparent and orange samples under UV irradiation; (d) pre-sintered 0.1%Mn∶KGO powder; (e) crystal formed by melting the pre-sintered powder (Fig.(d)) in a muffle furnace; (f) luminescence images of the samples in Fig.(d) under UV irradiation;(g) luminescence images of the samples in Fig.(e) under UV irradiation
Fig.3 Photographs of KGO crystals with varying Mn-doping concentrations grown by the Czochralski method. (a) 0.1%Mn∶KGO crystal,where the inset illustrates the sampling regions for spectroscopy and ICP measurements alongside their corresponding designations; (b) pure KGO crystal; (c) 0.05%Mn∶KGO crystal; (d) 0.05%Mn,0.5%Si∶KGO crystal
| Sample | Average dry weight/g | Average buoyant weight/g | Density/(g·cm-3) |
|---|---|---|---|
| KGO-as-grown crystal | 33.441 7 | 25.650 0 | 4.292 |
| KGO-crucible residue | 71.448 4 | 54.647 7 | 4.253 |
| 0.1%Mn∶KGO-E2 | 0.767 6 | 0.588 7 | 4.287 |
| 0.1%Mn∶KGO-I1 | 0.357 2 | 0.274 5 | 4.315 |
| ICSD#3169 KGO (calculated) | 4.292 |
Table 1 Densities of the KGO crystal samples
| Sample | Average dry weight/g | Average buoyant weight/g | Density/(g·cm-3) |
|---|---|---|---|
| KGO-as-grown crystal | 33.441 7 | 25.650 0 | 4.292 |
| KGO-crucible residue | 71.448 4 | 54.647 7 | 4.253 |
| 0.1%Mn∶KGO-E2 | 0.767 6 | 0.588 7 | 4.287 |
| 0.1%Mn∶KGO-I1 | 0.357 2 | 0.274 5 | 4.315 |
| ICSD#3169 KGO (calculated) | 4.292 |
| Sample | a/Å | c/Å |
|---|---|---|
| KGO-FZ-T | 11.765 2 | 9.786 0 |
| KGO-FZ-O | 11.812 5 | 9.795 1 |
| KGO-TGFM | 11.812 5 | 9.798 9 |
| ICSD#31969 KGO | 11.84 | 9.80 |
Table 2 Lattice parameters of the KGO crystal samples
| Sample | a/Å | c/Å |
|---|---|---|
| KGO-FZ-T | 11.765 2 | 9.786 0 |
| KGO-FZ-O | 11.812 5 | 9.795 1 |
| KGO-TGFM | 11.812 5 | 9.798 9 |
| ICSD#31969 KGO | 11.84 | 9.80 |
| Supercell model | V/Å3 | CP-a/Å | CP-c/Å | aBL/Å | Voct/Å3 | Bav/(°)2 | DI |
|---|---|---|---|---|---|---|---|
| KGO112-K24Ge48O108 | 2 500.20 | 12.016 2 | 19.994 6 | Ge1 1.947 2 Ge2 1.917 6 | 9.837 9 9.392 7 | 1.565 1 2.388 9 | 0 0.005 9 |
| KGO112-Ge1 | 2 498.82 | 12.010 8 | 20.001 5 | 1.946 2 | 9.809 4 | 4.721 9 | 0 |
| KGO112-Ge2 | 2 497.32 | 12.011 7 | 19.986 5 | 1.913 8 | 9.343 3 | 0.859 6 | 0.006 8 |
Table 3 Optimized crystal structure parameters of the KGO model
| Supercell model | V/Å3 | CP-a/Å | CP-c/Å | aBL/Å | Voct/Å3 | Bav/(°)2 | DI |
|---|---|---|---|---|---|---|---|
| KGO112-K24Ge48O108 | 2 500.20 | 12.016 2 | 19.994 6 | Ge1 1.947 2 Ge2 1.917 6 | 9.837 9 9.392 7 | 1.565 1 2.388 9 | 0 0.005 9 |
| KGO112-Ge1 | 2 498.82 | 12.010 8 | 20.001 5 | 1.946 2 | 9.809 4 | 4.721 9 | 0 |
| KGO112-Ge2 | 2 497.32 | 12.011 7 | 19.986 5 | 1.913 8 | 9.343 3 | 0.859 6 | 0.006 8 |
| Sample | T@650 nm/% | UV cutoff edge/nm | Optical band gap/eV | |
|---|---|---|---|---|
| 0.1%Mn∶KGO-E1 | 85.2 | 0.83 | 233.0 | 4.95 |
| 0.05%Mn∶KGO | 86.6 | 0.28 | 229.5 | 5.31 |
| 0.05%Mn,0.5%Si∶KGO | 61.1 | 1.89 | 231.5 | 5.00 |
Table 4 Transmittance and absorption coefficients of the KGO crystal samples
| Sample | T@650 nm/% | UV cutoff edge/nm | Optical band gap/eV | |
|---|---|---|---|---|
| 0.1%Mn∶KGO-E1 | 85.2 | 0.83 | 233.0 | 4.95 |
| 0.05%Mn∶KGO | 86.6 | 0.28 | 229.5 | 5.31 |
| 0.05%Mn,0.5%Si∶KGO | 61.1 | 1.89 | 231.5 | 5.00 |
| Sample | CTB/cm-1 | 4A2g→4T1g,a/cm-1 | 4A2g→2T2g/cm-1 | 4A2g→4T2g/cm-1 | 2Eg→4A2g/cm-1 | R2 |
|---|---|---|---|---|---|---|
| KGO-E1 | 34 444 | 28 933 | 24 972 | 21 601 | 15 337 | 0.997 4 |
| KGO-E2 | 34 795 | 28 913 | 24 222 | 21 565 | 15 337 | 0.997 6 |
| 0.1%Mn∶KGO | 34 667 | 29 213 | 24 966 | 21 623 | 15 337 | 0.998 1 |
| 0.05%Mn∶KGO | 34 610 | 29 662 | 24 530 | 21 606 | 15 337 | 0.997 8 |
| 0.05%Mn,0.5%Si∶KGO | 34 599 | 29 272 | 25 352 | 21 580 | 15 337 | 0.999 1 |
Table 5 Spectroscopic parameters of the Mn∶KGO crystal
| Sample | CTB/cm-1 | 4A2g→4T1g,a/cm-1 | 4A2g→2T2g/cm-1 | 4A2g→4T2g/cm-1 | 2Eg→4A2g/cm-1 | R2 |
|---|---|---|---|---|---|---|
| KGO-E1 | 34 444 | 28 933 | 24 972 | 21 601 | 15 337 | 0.997 4 |
| KGO-E2 | 34 795 | 28 913 | 24 222 | 21 565 | 15 337 | 0.997 6 |
| 0.1%Mn∶KGO | 34 667 | 29 213 | 24 966 | 21 623 | 15 337 | 0.998 1 |
| 0.05%Mn∶KGO | 34 610 | 29 662 | 24 530 | 21 606 | 15 337 | 0.997 8 |
| 0.05%Mn,0.5%Si∶KGO | 34 599 | 29 272 | 25 352 | 21 580 | 15 337 | 0.999 1 |
| Sample | Dq | B | C | Dq /B | β1 |
|---|---|---|---|---|---|
| K2SrGe8O18 phosphor[ | 2 336.4 | 800.1 | 3 064.4 | 2.92 | 0.991 |
| K2BaGe8O18 phosphor[ | 2 164.5 | 654.0 | 3 345.5 | 3.31 | 0.960 |
| LiBaGe4O9 crystal[ | 2 175.2 | 813.0 | 3 235.7 | 2.68 | 1.028 |
| KGO-E1 | 2 160.1 | 701.0 | 3 347.2 | 3.08 | 0.985 |
| KGO-E2 | 2 156.5 | 703.3 | 3 342.5 | 3.07 | 0.985 |
| 0.1%Mn∶KGO | 2 162.3 | 731.4 | 3 280.1 | 2.96 | 0.989 |
| 0.05%Mn∶KGO | 2 160.6 | 788.5 | 3 156.1 | 2.74 | 1.000 |
| 0.05%Mn,0.5%Si∶KGO | 2 158.0 | 744.1 | 3 252.7 | 2.90 | 0.991 |
Table 6 Crystal field parameters Dq,B,C,and β1 of selected Mn4+-doped germanate phosphors
| Sample | Dq | B | C | Dq /B | β1 |
|---|---|---|---|---|---|
| K2SrGe8O18 phosphor[ | 2 336.4 | 800.1 | 3 064.4 | 2.92 | 0.991 |
| K2BaGe8O18 phosphor[ | 2 164.5 | 654.0 | 3 345.5 | 3.31 | 0.960 |
| LiBaGe4O9 crystal[ | 2 175.2 | 813.0 | 3 235.7 | 2.68 | 1.028 |
| KGO-E1 | 2 160.1 | 701.0 | 3 347.2 | 3.08 | 0.985 |
| KGO-E2 | 2 156.5 | 703.3 | 3 342.5 | 3.07 | 0.985 |
| 0.1%Mn∶KGO | 2 162.3 | 731.4 | 3 280.1 | 2.96 | 0.989 |
| 0.05%Mn∶KGO | 2 160.6 | 788.5 | 3 156.1 | 2.74 | 1.000 |
| 0.05%Mn,0.5%Si∶KGO | 2 158.0 | 744.1 | 3 252.7 | 2.90 | 0.991 |
| Sample | λex/nm | IQE/% | AE/% | EQE/% |
|---|---|---|---|---|
| K2SrGe8O18 phosphor[ | 287 | 35.50 | 52.96 | 18.80 |
| K2BaGe8O18 phosphor[ | 365 | 32.90 | ||
| Ba2GeO4 phosphor[ | 290 | 22.53 | — | |
(Mg,Ba)3Al2GeO8 phosphor[ Mg3Al2GeO8 phosphor[ | 284 284 | — — | — — | 49.35 29.44 |
BaGe4O9 phosphor[ SrGe4O9 phosphor[ | 440 430 | 50.00 46.00 | ||
| LiNaGe4O9 phosphor[ | 310 450 | 78.00 48.00 | ||
| LiNaGe4O9 glass-ceramic[ | — | 37.50 | ||
| Mn∶KGO phosphor[ | 300 460 470 | 45.00 33.50 33.80 | ||
| 0.05%Mn∶KGO | 460 | 46.10 | 17.70 | 8.16 |
| 0.05%Mn,0.5%Si∶KGO | 460 | 27.10 | 25.50 | 4.34 |
| 0.1%Mn∶KGO-E1 | 460 | 48.30 | 37.00 | 17.87 |
| E2 | 460 | 41.60 | 60.60 | 25.21 |
| E3 | 460 | 38.90 | 60.60 | 23.57 |
| I1 | 460 | 46.70 | 43.60 | 20.36 |
| I2 | 460 | 35.10 | 40.70 | 14.29 |
| I3 | 460 | 41.10 | 47.00 | 19.32 |
Table 7 Internal and external quantum efficiencies (IQE/EQE) of Mn4+-doped germanate materials
| Sample | λex/nm | IQE/% | AE/% | EQE/% |
|---|---|---|---|---|
| K2SrGe8O18 phosphor[ | 287 | 35.50 | 52.96 | 18.80 |
| K2BaGe8O18 phosphor[ | 365 | 32.90 | ||
| Ba2GeO4 phosphor[ | 290 | 22.53 | — | |
(Mg,Ba)3Al2GeO8 phosphor[ Mg3Al2GeO8 phosphor[ | 284 284 | — — | — — | 49.35 29.44 |
BaGe4O9 phosphor[ SrGe4O9 phosphor[ | 440 430 | 50.00 46.00 | ||
| LiNaGe4O9 phosphor[ | 310 450 | 78.00 48.00 | ||
| LiNaGe4O9 glass-ceramic[ | — | 37.50 | ||
| Mn∶KGO phosphor[ | 300 460 470 | 45.00 33.50 33.80 | ||
| 0.05%Mn∶KGO | 460 | 46.10 | 17.70 | 8.16 |
| 0.05%Mn,0.5%Si∶KGO | 460 | 27.10 | 25.50 | 4.34 |
| 0.1%Mn∶KGO-E1 | 460 | 48.30 | 37.00 | 17.87 |
| E2 | 460 | 41.60 | 60.60 | 25.21 |
| E3 | 460 | 38.90 | 60.60 | 23.57 |
| I1 | 460 | 46.70 | 43.60 | 20.36 |
| I2 | 460 | 35.10 | 40.70 | 14.29 |
| I3 | 460 | 41.10 | 47.00 | 19.32 |
Fig.18 Temperature-dependent luminescence properties of the Mn∶KGO crystal at low temperatures. (a) Low-temperature emission spectra; (b) temperature dependence of the integrated PL intensity and zero-phonon line (ZPL) peak intensity; (c) temperature-dependent fluorescence decay curves
Fig.19 Comparison of the temperature-dependent luminescence properties between the Mn∶KGO crystal and phosphor at elevated temperatures. Temperature-dependent emission spectra of the crystal (a) and phosphor (b),respectively; temperature-dependent fluorescence decay curves of the crystal (c) and phosphor (d),respectively; (e) temperature dependence of the integrated PL intensity
| Sample | CIE 1931 chromaticity coordinates (X,Y) | Color purity/% |
|---|---|---|
| 0.1%Mn∶KGO | (0.724 1,0.275 8) | 98.24 |
| 0.05%Mn∶KGO | (0.724 0,0.276 0) | 98.21 |
| 0.05%Mn,0.5%Si∶KGO | (0.724 2,0.275 8) | 98.26 |
Table 8 CIE chromaticity coordinates and color purity parameters of Mn∶KGO crystals
| Sample | CIE 1931 chromaticity coordinates (X,Y) | Color purity/% |
|---|---|---|
| 0.1%Mn∶KGO | (0.724 1,0.275 8) | 98.24 |
| 0.05%Mn∶KGO | (0.724 0,0.276 0) | 98.21 |
| 0.05%Mn,0.5%Si∶KGO | (0.724 2,0.275 8) | 98.26 |
Fig.20 Spectral performance and chromaticity coordinates of LED devices packaged with the Mn∶KGO crystal. Electroluminescence spectra of the plant-growth LED device (a) and the white LED device (b); (c) CIE chromaticity diagram of the Mn∶KGO crystal and the LED devices
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