Near-Infrared Long Afterglow in Fe<sup>3+</sup>-Activated Mg<sub>2</sub>SnO<sub>4</sub> for Self-Sustainable Night Vision
Minzhong Li, Yahong Jin, Lifang Yuan, Bo Wang, Haoyi Wu, Yihua Hu, Feng Wang
Abstract
The advent of near-infrared (NIR) afterglow in Cr 3+ -doped materials has stimulated considerable interest in technological applications owing to the sustainable emission of light with good penetrability. However, the development of Cr 3+ -free NIR afterglow phosphors with high efficiency, low cost, and precise spectral tunability is still an open question. Herein, we report a novel Fe 3+ -activated NIR long afterglow phosphor composed of Mg 2 SnO 4 (MSO), in which Fe 3+ ions occupy the tetrahedral [Mg–O 4 ] and octahedral [Sn/Mg–O 6 ] sites, giving rise to a broadband NIR emission spanning 720–789 nm. On account of energy-level alignment, the electrons released from the traps show a preferential return to the excited energy level of Fe 3+ in tetrahedral sites through tunneling, leading to a single-peak NIR afterglow centered at 789 nm with a full-width at half-maximum (fwhm) of 140 nm. The high-efficiency NIR afterglow, showing a record persistent time lasting over 31 h among Fe 3+ -based phosphors, is demonstrated as a self-sustainable light source for night vision applications. This work not only provides a novel Fe 3+ -doped high-efficiency NIR afterglow phosphor for technological applications but also establishes practical guidance for rational tuning of afterglow emissions.