
人工晶体学报 ›› 2026, Vol. 55 ›› Issue (6): 910-929.DOI: 10.16553/j.cnki.issn1000-985x.2026.0037
宋青松1,2(
), 刘坚2, 张帆1, 张超逸1,3, 王无敌1, 曹笑1, 钱新宇1, 唐慧丽1, 王庆国1, 张晨波1, 刘波1, 徐晓东2, 徐军1(
)
收稿日期:2026-03-09
出版日期:2026-06-20
发布日期:2026-07-07
通信作者:
徐军,博士,教授。E-mail:15503@tongji.edu.cn作者简介:宋青松(1990—),男,重庆市人,博士研究生。E-mail:qingsong_song@126.com
基金资助:
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
摘要: 针对传统Mn4+掺杂多晶氧化物荧光粉体面临的严重热猝灭瓶颈,本研究采用提拉法生长了新型Mn4+∶K2Ge4O9(Mn∶KGO)单晶。结合密度泛函理论(DFT)计算,揭示了该体系中格位依赖的双重热猝灭机制:占据Ge1位点的Mn4+受宇称选律制约,触发了载流子自电离过程;而占据主发光中心Ge2位点的Mn4+与价带发生强烈共价杂化,迫使电荷迁移态能量显著下移。研究表明,相较于多晶粉体,单晶的连续晶格结构有效阻断了非辐射跃迁通道,将热猝灭温度提升了6.2 ℃,内量子效率实现了44%的大幅跃升,达到48.3%。器件应用评估显示,将该单晶集成于白光发光二极管(LED)封装后,系统的显色指数提升7.5,相关色温降低逾2 000 K,成功驱动了冷白光向暖白光的转变;同时,该系统的664 nm的深红光发射光谱与植物光敏色素的特征吸收带高度契合。本研究开发了低熔点Mn4+掺杂氧化物晶体,为大功率固态照明及植物生长照明应用提供了极具潜力的单晶红光材料。
中图分类号:
宋青松, 刘坚, 张帆, 张超逸, 王无敌, 曹笑, 钱新宇, 唐慧丽, 王庆国, 张晨波, 刘波, 徐晓东, 徐军. Mn4+掺杂K2Ge4O9单晶的生长、猝灭机制及其发光性能研究[J]. 人工晶体学报, 2026, 55(6): 910-929.
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.
图2 探索阶段制备的Mn∶KGO样品实物照片及其在紫外灯下的发光图。(a)浮区炉中Mn∶KGO上下料棒熔融滴落后的样品(透明与橘黄色部分);(b)浮区法熔滴的透明样品;(c)透明与橘黄色样品在紫外灯照射下的照片;(d)0.1%Mn∶KGO预烧结粉体;(e)图(d)中粉体在马弗炉中熔化后形成的晶体;(f)图(d)中粉体在紫外灯照射下的照片;(g)图(e)中晶体在紫外灯照射下的照片
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
图3 提拉法生长的不同Mn掺杂浓度KGO晶体照片。(a)0.1%Mn∶KGO晶体,插图显示了用于光谱与ICP测试的取样区域及对应命名;(b)纯KGO晶体;(c)0.05%Mn∶KGO晶体;(d)0.05%Mn,0.5%Si∶KGO晶体。
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 |
表1 KGO晶体样品的密度
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 |
表2 KGO晶体样品的晶胞参数
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 |
表3 KGO模型结构优化后的晶体结构参数
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 |
表4 KGO晶体样品的透过率及吸收系数
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 |
表5 Mn∶KGO晶体的光谱参数
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 |
表6 部分Mn4+掺杂锗酸盐荧光材料的晶体场参数Dq 、B、C及 β1
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 |
表7 Mn4+掺杂锗酸盐材料的内、外量子效率
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 |
图18 Mn∶KGO晶体在低温下的变温发光特性。(a)低温发射光谱;(b)PL积分强度与ZPL峰值强度随温度的变化曲线;(c)变温荧光衰减曲线
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
图19 Mn∶KGO晶体与荧光粉在高温下的变温发光特性对比。晶体(a)和荧光粉(b)的变温发射光谱;晶体(c)和荧光粉(d)的变温荧光衰减曲线;(e)PL积分强度随温度的变化曲线
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 |
表8 Mn∶KGO晶体的CIE色坐标及色纯度参数
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 |
图20 基于Mn∶KGO晶体封装LED器件的光谱性能与色度坐标。植物补光LED(a)和白光LED器件(b)的电致发光光谱;(c)Mn∶KGO晶体与LED器件的CIE色度坐标图
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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