Achieving high-performance near-infrared Cr3+-activated phosphor via A&C lattice sites cosubstitution strategy in garnet for plant lighting

https://doi.org/10.1007/s40843-025-3691-9 

Near-infrared (NIR) spectroscopy has significantly advanced NIR light sources. However, creating NIR emitters with optimal luminescence properties, high thermal stability, and adjustable emission peaks poses a critical challenge for future smart NIR devices. We introduced a chemical unit cosubstitution strategy by incorporating Ca²⁺ and Sn⁴⁺ ions into the garnet structure. Through this approach, Y_3−yCa_yGa_4.95−ySn_yG₁₂:0.05Cr³⁺ (y = 0–1) phosphors were developed by modulating the A&C ligands, resulting in emission centers ranging from 708 to 768 nm. The modified local environment of Cr³⁺ accounts for the increased light intensity (2.71 times) and broadening observed. Furthermore, this study investigated the impact of varying Cr³⁺ concentrations (Y_2.6Ca_0.4Ga_4.6−xSn_0.4G₁₂:xCr³⁺) on the production of high-performance phosphors. Compared with Y₃Ga_4.93G₁₂:0.07Cr³⁺, the optimized phosphor exhibited exceptional external quantum efficiency (EQE = 34.96%). The luminescence enhancement is attributed to an increase in radiative transitions caused by octahedral Jahn-Teller distortion, whereas the notable thermal stability (91.3% at 423 K) is attributed to the presence of weak electron-phonon coupling (EPC) and oxygen vacancy (O_V) defects. Finally, by combining it with a 450 nm blue LED chip, we constructed a near-infrared phosphor-converted LED (NIR pc-LED) device with superior electroluminescence efficiency (18.8% @ 100 mA), increasing the ultralow quenching rate (< 5% intensity loss after 30 days of operation) and demonstrating remarkable performance in plant lighting applications.