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Quantitative insights into the chemical trend of four-coordinated Mn2+ emission in inorganic compounds

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Abstract Pursuing of the capabilities of predicting the luminescent properties of 3d ions doped phosphors before performing experimental exploitation is always a focus of experimental investigation, which is still suspended… Click to show full abstract

Abstract Pursuing of the capabilities of predicting the luminescent properties of 3d ions doped phosphors before performing experimental exploitation is always a focus of experimental investigation, which is still suspended so far. As a tentative step in this work, we developed a simple relationship to predict the emission peak of Mn2+ only based on its three local-environmental-related parameters: the average bond length between Mn2+ and its ligand anions, ligand orbitals energy and the distortion of its crystal field by focusing on tetrahedral sites. With the relationship, it offers a possible and easier approach to access the emission peaks of Mn2+ in a tetrahedral site, as we find the emission energy increases dominantly with the increase of the bond lengths between Mn2+ and its ligand anions and decreases with the rise of the ligand orbitals energy, while the factor of crystal field distortion could make the emission of Mn2+ red-shifted normally in a margin of several dozens of meV with a rare exception for an extremely large crystal field distortion with larger red-shift about 100–200 meV. We believe this high prediction accuracy of Mn2+ emission peak energy could facilitate more experimental efforts in synthesizing new Mn2+ activated phosphor with target emission position in future.

Keywords: mn2; quantitative insights; energy; mn2 emission; crystal field; emission

Journal Title: Journal of Luminescence
Year Published: 2020

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