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Mn–Mn Magnetic Coupling Interaction-Induced Red Emission in a Tetra-Coordinated Lattice

Wei Wang, Yi Wei, Lei Qiu, Мaxim S. Моlokeev, Hang Yang, Huiru Liu, Rui Gao, Mengyu Guan, Dong Tu, Guogang Li

2024Chemistry of Materials21 citationsDOI

Abstract

Strong magnetic coupling interactions originating from a short Mn–Mn distance in some heavy Mn 2+ -doped matrices have important effects on luminescence of single Mn 2+ ions and close-knit Mn 2+ –Mn 2+ pairs. However, the intrinsic mechanism of controlling spectral regulation remains elusive since the underlying relationship among Mn–Mn distances, magnetic coupling interactions, and optical properties is unclear. Herein, we create an unusual red emission (620 nm) of Mn 2+ in a typical tetra-coordinated lattice of Li 2 CdGeO 4 by simply enhancing the Mn 2+ -doped level in addition to regular green emission (528 nm). Although the dual emission peaks occupy the same tetra-coordinated crystallographic lattice of CdO 4, different temperature-dependent emission behaviors are observed, which expands a possibility in optical thermometry sensors. Detailed Mn–Mn distances are calculated via Rietveld refinement analysis, and their effects on the Mn–Mn coupling interactions are evaluated. Furthermore, the Mn–Mn coupling interaction types are identified through electron spin resonance and magnetic measurements. The continuously decreasing distances between Mn 2+ ions strengthen the dipole–dipole coupling effect, resulting in the atypical red emission in a tetra-coordinated lattice environment. These findings elucidate the spectral regulation mechanism from the perspective of magnetic coupling interactions, providing a new pathway to regulate Mn 2+ -related emission.

Topics & Concepts

TetraLattice (music)Coupling (piping)ManganeseMaterials scienceInductive couplingCondensed matter physicsChemistryCrystallographyPhysicsMetallurgyQuantum mechanicsMedicinal chemistryAcousticsMagnetic properties of thin filmsZnO doping and propertiesLuminescence Properties of Advanced Materials