Strategic Tuning of Photophysical Response in the Polyhedral Framework of the Garnet Structure toward White Light-Emitting Devices with Enhanced Color Rendering
Amrithakrishnan Bindhu, Jawahar I. Naseemabeevi, Subodh Ganesanpotti
Abstract
Designing a single-phase phosphor with high quantum efficiency and full spectrum emission is inevitable for today’s scientific world. Herein, an optimal strategy for realizing white emission in a single component matrix is envisaged based on the structure–property-design-device policy. Cationic substitution corresponding to polyhedral expansion and contraction in A 2 A′B 2 V 3 O 12 confirms the existence of strong and intricate linkage in the garnet structure. The dodecahedral expansion causes compression of VO 4 tetrahedra and a blue shift. The direct correlation of V–O bond distance with red shift validates the distortion of the VO 4 tetrahedra. The interdependence of photophysical properties via cationic substitution and subsequent correlation of the V–O bond distance with emission bands enabled the tailoring of phosphor-CaSrNaMg 2 V 3 O 12 with a high quantum efficiency of 52% and excellent thermal stability of 0.39 eV. Bright warm white light-emitting diode (WLED) devices are fabricated based on Eu 3+ and Sm 3+ -activators. A high quantum efficiency-74% is obtained for the designed Eu 3+ phosphor. CIE coordinates near the achromatic point (0.329, 0.366), low CCT-5623 K, and high color rendering index (CRI)-87 are obtained for the single-phase WLED device. This work puts forth a new direction for designing and engineering promising WLEDs with enhanced color rendering based on single-phase phosphors with full spectrum emission.