Green-emissive Ce:LuAlO-AlO nanoceramics elaborated glass crystallization for high-power laser lighting applications

Transparent Ce:Lu 3 Al 5 O 12 (Ce:LuAG) phosphor ceramics are regarded as the most promising green color conversion materials in the next-generation of laser diode (LD) lighting. However, the insufficient scattering of incident blue laser and poor heat quenching seriously prevent the application of...

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Published in:Journal of materials chemistry. C, Materials for optical and electronic devices Materials for optical and electronic devices, 2024-05, Vol.12 (2), p.7188-7196
Main Authors: Fu, Jie, Feng, Shaowei, Genevois, Cécile, Véron, Emmanuel, Yang, Yafeng, Wang, Hui, Ma, Zhibiao, Bai, Linghan, Xu, Wenlong, Fan, Ruyu, Wang, Chengzhi, Allix, Mathieu, Li, Jianqiang
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container_title Journal of materials chemistry. C, Materials for optical and electronic devices
container_volume 12
creator Fu, Jie
Feng, Shaowei
Genevois, Cécile
Véron, Emmanuel
Yang, Yafeng
Wang, Hui
Ma, Zhibiao
Bai, Linghan
Xu, Wenlong
Fan, Ruyu
Wang, Chengzhi
Allix, Mathieu
Li, Jianqiang
description Transparent Ce:Lu 3 Al 5 O 12 (Ce:LuAG) phosphor ceramics are regarded as the most promising green color conversion materials in the next-generation of laser diode (LD) lighting. However, the insufficient scattering of incident blue laser and poor heat quenching seriously prevent the application of transparent Ce:LuAG phosphor ceramics in high-quality LD-driven lighting, especially at high input power density. In view of this, a biphasic Ce:LuAG-Al 2 O 3 green phosphor ceramic is proposed in this study. Using an excessive Al 2 O 3 component design strategy, the Al 2 O 3 secondary phase is in situ generated in the resulting ceramic material via the full bulk glass crystallization method. The in situ generated Al 2 O 3 secondary phase can serve as a light scattering center and has good thermal conductivity. Therefore, the luminescence properties and thermal stability of transparent Ce:LuAG-Al 2 O 3 phosphor ceramics are greatly enhanced compared to Ce:LuAG. An ultrahigh luminous flux (LF) of 5124.7 lm and an excellent luminous density of 4235.5 lm mm −2 are achieved in LD-driven lighting under 450 nm high power density laser excitation (29.83 W mm −2 ), which has been almost the best performance of transparent Ce:LuAG ceramics in LD lighting to date. A maximum luminous efficiency of 247.9 lm W −1 (4.38 W mm −2 ) is also obtained. These results demonstrate that the transparent Ce:LuAG-Al 2 O 3 nanoceramics prepared in this work are promising green-emitting color converters to achieve high-brightness and excellent luminous density for high power LD lighting. The excessive Al 2 O 3 component design strategy could also further drive the development of garnet-based transparent ceramics in the field of high-power LD lighting. Ce:LuAG-Al 2 O 3 nanoceramics prepared through glass crystallization present an ultrahigh luminous flux (LF) of 5124.7 lm and an excellent luminous density of 4235.5 lm mm −2 in LD-driven lighting.
doi_str_mv 10.1039/d4tc00616j
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However, the insufficient scattering of incident blue laser and poor heat quenching seriously prevent the application of transparent Ce:LuAG phosphor ceramics in high-quality LD-driven lighting, especially at high input power density. In view of this, a biphasic Ce:LuAG-Al 2 O 3 green phosphor ceramic is proposed in this study. Using an excessive Al 2 O 3 component design strategy, the Al 2 O 3 secondary phase is in situ generated in the resulting ceramic material via the full bulk glass crystallization method. The in situ generated Al 2 O 3 secondary phase can serve as a light scattering center and has good thermal conductivity. Therefore, the luminescence properties and thermal stability of transparent Ce:LuAG-Al 2 O 3 phosphor ceramics are greatly enhanced compared to Ce:LuAG. An ultrahigh luminous flux (LF) of 5124.7 lm and an excellent luminous density of 4235.5 lm mm −2 are achieved in LD-driven lighting under 450 nm high power density laser excitation (29.83 W mm −2 ), which has been almost the best performance of transparent Ce:LuAG ceramics in LD lighting to date. A maximum luminous efficiency of 247.9 lm W −1 (4.38 W mm −2 ) is also obtained. These results demonstrate that the transparent Ce:LuAG-Al 2 O 3 nanoceramics prepared in this work are promising green-emitting color converters to achieve high-brightness and excellent luminous density for high power LD lighting. The excessive Al 2 O 3 component design strategy could also further drive the development of garnet-based transparent ceramics in the field of high-power LD lighting. 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Therefore, the luminescence properties and thermal stability of transparent Ce:LuAG-Al 2 O 3 phosphor ceramics are greatly enhanced compared to Ce:LuAG. An ultrahigh luminous flux (LF) of 5124.7 lm and an excellent luminous density of 4235.5 lm mm −2 are achieved in LD-driven lighting under 450 nm high power density laser excitation (29.83 W mm −2 ), which has been almost the best performance of transparent Ce:LuAG ceramics in LD lighting to date. A maximum luminous efficiency of 247.9 lm W −1 (4.38 W mm −2 ) is also obtained. These results demonstrate that the transparent Ce:LuAG-Al 2 O 3 nanoceramics prepared in this work are promising green-emitting color converters to achieve high-brightness and excellent luminous density for high power LD lighting. The excessive Al 2 O 3 component design strategy could also further drive the development of garnet-based transparent ceramics in the field of high-power LD lighting. 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C, Materials for optical and electronic devices</jtitle><date>2024-05-23</date><risdate>2024</risdate><volume>12</volume><issue>2</issue><spage>7188</spage><epage>7196</epage><pages>7188-7196</pages><issn>2050-7526</issn><eissn>2050-7534</eissn><abstract>Transparent Ce:Lu 3 Al 5 O 12 (Ce:LuAG) phosphor ceramics are regarded as the most promising green color conversion materials in the next-generation of laser diode (LD) lighting. However, the insufficient scattering of incident blue laser and poor heat quenching seriously prevent the application of transparent Ce:LuAG phosphor ceramics in high-quality LD-driven lighting, especially at high input power density. In view of this, a biphasic Ce:LuAG-Al 2 O 3 green phosphor ceramic is proposed in this study. Using an excessive Al 2 O 3 component design strategy, the Al 2 O 3 secondary phase is in situ generated in the resulting ceramic material via the full bulk glass crystallization method. The in situ generated Al 2 O 3 secondary phase can serve as a light scattering center and has good thermal conductivity. Therefore, the luminescence properties and thermal stability of transparent Ce:LuAG-Al 2 O 3 phosphor ceramics are greatly enhanced compared to Ce:LuAG. An ultrahigh luminous flux (LF) of 5124.7 lm and an excellent luminous density of 4235.5 lm mm −2 are achieved in LD-driven lighting under 450 nm high power density laser excitation (29.83 W mm −2 ), which has been almost the best performance of transparent Ce:LuAG ceramics in LD lighting to date. A maximum luminous efficiency of 247.9 lm W −1 (4.38 W mm −2 ) is also obtained. These results demonstrate that the transparent Ce:LuAG-Al 2 O 3 nanoceramics prepared in this work are promising green-emitting color converters to achieve high-brightness and excellent luminous density for high power LD lighting. The excessive Al 2 O 3 component design strategy could also further drive the development of garnet-based transparent ceramics in the field of high-power LD lighting. Ce:LuAG-Al 2 O 3 nanoceramics prepared through glass crystallization present an ultrahigh luminous flux (LF) of 5124.7 lm and an excellent luminous density of 4235.5 lm mm −2 in LD-driven lighting.</abstract><doi>10.1039/d4tc00616j</doi><tpages>9</tpages></addata></record>
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title Green-emissive Ce:LuAlO-AlO nanoceramics elaborated glass crystallization for high-power laser lighting applications
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