Thermodynamic Stabilization and Cr ³⁺ Luminescence Tuning in Gd ₃ Al ₅ O Qinghong Meng, Jiaming Yuan, Zhijun Xu, Xiangming Li, Wanjun Yu, Rong Feng, Xintao Zhang, Ji‐Guang Li

ABSTRACT

To explore broadband near‐infrared (NIR) emission phosphor based on the thermodynamic metastable Gd ₃ Al ₅ O ₁₂ garnet, a new strategy of Ca ²⁺ ‐Sn ⁴⁺ pairs substituting for Gd ³⁺ ‐Al ³⁺ was utilized to stabilize the lattice, followed by using Ga ³⁺ doping to tune the crystal structure, Cr ³⁺ local coordination environment, and luminescence. Then the novel Gd _1.02 Ca _1.98 Al _{3− y} Ga _y Sn _1.98 O ₁₂ :0.02Cr ³⁺ (GCAGSO:Cr) phosphors were successfully devised and fabricated, and systematic research revealed that increased Ga ³⁺ incorporation induced an enhanced degree of the [(Sn,Ga,Cr)O ₆ ] octahedron distortion, weakened the magnitude of the crystal field Cr ³⁺ experienced, and red‐shifted/broadened the emission band. The optimal phosphor exhibits efficient broadband NIR emission and outstanding thermal stability ( I _423K  = 84.3%, S  = 3.52, Δ E _a  = 0.31 eV), with a maximum center at ∼782 nm, a full‐width at half‐maximum of ∼138 nm, and internal/external quantum efficiencies of ∼80.3%/24.2%. The constructed pc‐NIR‐LED adopting this optimal phosphor manifests desirable luminous performance (output power ∼19.05 mW, efficiency ∼8.24%), demonstrating promise for practical applications in non‐invasive biological imaging, non‐destructive inspection, and night vision.