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High-brightness far-red light plays a key role in increasing photosynthetic efficiency and thus crop production in plant factories, as it regulates the entire lifecycle of plants, from seed germination to flowering and fruiting. However, the optical power and efficiency of far-red phosphor-converted light-emitting diodes, which are inexpensive solid-state light sources, are still limited due to the poor chemical stability and low thermal conductivity of conventional phosphor‒silicone composite converters. Here, a series of Cr3+-activated far-red-emitting silicate ceramics with near-unity internal quantum efficiency and near-zero thermal quenching were developed via a simple modified annealing method for full crystallization from the designed glass precursors. Furthermore, the local crystal field of octahedral Cr3+ sites in Y2CaAl4SiO12:Cr3+ is strengthened by cation substitution of Ba2+ for Ca2+ so that the emission spectrum is largely regulated from a broad near-infrared band to a narrow far-red band that overlaps well with the absorption band of the phytochrome (Pfr) state. Finally, the optimized Y2Ca0.3Ba0.7Al4SiO12:Cr3+ ceramic enables the realization of a high wall-plug efficiency of 27% for the far-red pc-LED and a record output optical power exceeding 2.1 W for the laser-driven far-red light source, highlighting its tremendous potential to serve as all-inorganic color converters for high-power plant-growth light sources.

This is an open access article under the terms of the Creative Commons Attribution 4.0 International License (CC BY 4.0, http://creativecommons.org/licenses/by/4.0/).
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