Investigation on Anomalous Thermal Quenching of Mn <sup>4+</sup> Luminescence in A <sub>2</sub> XF <sub>6</sub> :Mn <sup>4+</sup>
Sadao Adachi
Abstract
Studying luminescence properties of phosphor materials is not only of scientific interest, but also technological importance. Here, we investigate luminescence intensity as a function of temperature for Mn 4+ -activated fluoride and oxide phosphors. A recent study suggested that an anomalous increase in Mn 4+ luminescence intensity ( I PL ) with increasing lattice temperature ( T ) in various fluoride phosphors is likely a pitfall caused by a diminishment in the optical path lengths of the spectrofluorometer stemming from lattice thermal expansion. We show that such anomalous enhancement of I PL is due to the increased phonon number that makes it possible to gain the parity and spin-forbidden 2 E g → 4 A 2 g transitions rather than an extrinsic effect of lattice thermal expansion. The temperature dependence of the zero-phonon line emission intensity I ZPL may be a good indicator for deciding whether an observed anomaly of I PL is due to an intrinsic or an extrinsic effect because its intensity should in principle not be dependent on T . The experimental data on the Rb 2 GeF 6 :Mn 4+ fluoride and Cs 2 WO 2 F 4 :Mn 4+ oxyfluoride phosphors are presented as a direct verification of this. A discussion is also given on the 2 E g → 4 A 2 g transition properties in connection with the inelastic light scattering spectroscopy.