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Rapid sintering of high-efficiency phosphor-in-glass films for laser-driven light source

Pengfei Wang, Hang Lin, Guoxin Chen, W.T. Weng, Yue Xu, Yi Lin, Ju Xu, Yao Cheng, Yuansheng Wang

2025Nature Communications31 citationsDOIOpen Access PDF

Abstract

The development of advanced high-power-density laser-driven light source requires durable and color-tunable inorganic phosphor-in-glass film composites as color converter. One challenge remains for the phosphor-in-glass film is the thermal erosion and degradation of phosphor, as harsh condition or long duration time is required to densify the film for conventional sintering. Here we develop a rapid thermal annealing technique that achieves high film densification (porosity < 3%) within seconds utilizing high-power (>10 kW) infrared irradiation. As demonstrated by high-resolution electron microscopy observation, a trivial interfacial reaction occurs, leading to almost intact phosphor particles and thus restrained luminous loss. For instance, the red-emitting Sr0.8Ca0.2AlSiN3:Eu2+ exhibits a record internal quantum efficiency of 91.2% in the processed film and achieves a luminous flux of 2379 lm and efficacy of 140 lm W−1 after fabricating a phosphor wheel. This method reduces energy consumption, enables high-throughput screening, and offers material universality and design flexibility, paving the way for new opto-functional materials and applications. High-power laser lighting requires stable phosphor-in-glass films, but conventional sintering damages phosphors. Here, the authors develop infrared annealing which enables seconds-scale fabrication, minimizes interfacial damage and retains luminescence.

Topics & Concepts

PhosphorSinteringMaterials scienceLaserOptoelectronicsLight sourceSelective laser sinteringComposite materialOpticsPhysicsLuminescence Properties of Advanced MaterialsSolid State Laser TechnologiesPhotorefractive and Nonlinear Optics