Low-field microwave response and electron paramagnetic resonance identification of valence states of manganese including octahedral Mn5+ in YAlO3 and CaYAlO4

Abstract: Zero-field signal in the electron paramagnetic resonance spectrum of Mn +2 in silicate glassesMicrowave response near zero magnetic field has been observed in YAlO 3 and CaYAlO 4 crystals dilutely doped with Mn in concentration ranging from 0.005 to 0.2 at. %. The response is due to magnetic-field-dependent nonresonant microwave losses, which co-exist with normal electron paramagnetic resonance ͑EPR͒ absorption due to Mn 2ϩ , Mn 4ϩ , and Mn 5ϩ ions in YAlO 3 and CaYAlO 4 . The valence states of manganese have … Show more

“…As the temperature cools down from 300 K to 4.2 K, the microwave loss decreases at the beginning for all doping levels, presumably from a decrease in the phonon population and a very small (most likely an insignificant change) reduction in band conduction or hopping transport. [6][7][8][9][10][11][12] As the temperature cools down further, however, a significant increase of loss is observed in Ni doped samples, and the loss scales with Ni-doping concentration. The "turning point" (the temperature where loss tangent starts to increase) in the loss tangent curves varies with doping levels.…”

“…Optimized materials are insulating with minimal free carrier conduction. 6,7 The loss that is present in such materials has most often been attributed to anharmonic-phonons. [8][9][10][11][12] Impurity defects, 13 extended defects, 14 and surface states in pores 15 have been experimentally correlated to an increase in the loss tangent, and this has been attributed to the production of softer phonon modes with increased anharmonicity.…”

The dominance of paramagnetic loss in microwave dielectric ceramics at cryogenic temperatures

“…As the temperature cools down from 300 K to 4.2 K, the microwave loss decreases at the beginning for all doping levels, presumably from a decrease in the phonon population and a very small (most likely an insignificant change) reduction in band conduction or hopping transport. [6][7][8][9][10][11][12] As the temperature cools down further, however, a significant increase of loss is observed in Ni doped samples, and the loss scales with Ni-doping concentration. The "turning point" (the temperature where loss tangent starts to increase) in the loss tangent curves varies with doping levels.…”

“…Optimized materials are insulating with minimal free carrier conduction. 6,7 The loss that is present in such materials has most often been attributed to anharmonic-phonons. [8][9][10][11][12] Impurity defects, 13 extended defects, 14 and surface states in pores 15 have been experimentally correlated to an increase in the loss tangent, and this has been attributed to the production of softer phonon modes with increased anharmonicity.…”

The dominance of paramagnetic loss in microwave dielectric ceramics at cryogenic temperatures

“…These results suggest that the majority of photogenerated electrons (Ti(III)) are formed either via fast hole trapping at Mn substitutional sites or via direct excitation of Mn dopant atoms according to the reaction Note that Mn(III) (S ) 2) formed during excitation is an ion with an even number of electrons and is usually not observed using conventional X-band EPR due to commonly large zero field splitting and/or fast relaxation times. 18 Participation of Mn in light excitation suggests strong coupling of electronic states of Mn dopant atoms and TiO 2 lattice constituents. To confirm that these Mn atoms are incorporated in the TiO 2 lattice, we have investigated the samples in which Mn 2+ ions (6.3 × 10 -4 M, pH ) 3) are deliberately adsorbed on TiO 2 nanoparticles prepared with the same method.…”

Charge Separation and Surface Reconstruction:  A Mn²⁺ Doping Study

“…In fact, no potential candidate (including Mn) is reliably evidenced above the detection limit of EDXRF and optical absorption. On the other hand, the confirmation of the occurrence of Mn species comes from EPR spectra that show weak resonances (inset of figure 4) characterized by hyperfine structures composed by sextets of lines spaced by about 9 mT, as expected from paramagnetic hyperfine interactions of the electronic configuration of Mn 2+ ions with the I=5/2 nuclear spin of the 100% abundant 55 Mn [14].…”

Luminescence study of transition metal ions in natural magmatic and metamorphic yellow sapphires