Preparation and luminescence behaviour of perovskite LaAlO3:Tb3+ nanophosphors for innovative displays

Energy transfer mechanism of KAlF4:Dy3+, Eu3+ co-activated down-conversion phosphor as spectral converters: An approach towards improving photovoltaic efficiency by downshifting layer

Luminescence (nano)thermometry is an emerging and promising field for remote temperature sensing and thermal imaging of both the surface and interior of objects. While the field is dominated by trivalent lanthanide ions (Ln3+) the transition metal ions have a so far underestimated role in that regard, although their luminescence properties are far more sensitive to changes in the embedding host matrix than in the case of the Ln3+ ions. In this work, we demonstrate the potential of the abundant Fe3+ ion as a candidate for sensitive luminescence thermometry in the aluminate hosts MAl4O7 (M = Ca, Sr, Ba). Although this ion is usually considered an efficient luminescence quencher, it is shown that a targeted control of its luminescence properties makes this activator an interesting and only scarcely investigated alternative to the Ln3+ ions. We investigated the possibility for different modes of luminescence thermometry with Fe3+ (eventually co-doped with Tb3+ as internal thermally insensitive intensity reference), which include absolute intensity, ratiometric or lifetime thermometry. By selective changes in the Fe–O bond distances, it is possible to modulate the relative sensitivity towards values as high as around 2% K−1 at room temperature in CaAl4O7:Fe3+,Tb3+ and connected relative temperature uncertainties of around 0.3%.

/pdf/from-quencher-to-potent-activator-multimodal-luminescence-io4a5d59cb.pdf

From quencher to potent activator – Multimodal luminescence thermometry with Fe3+ in the oxides MAl4O7 (M = Ca, Sr, Ba)

Structural, morphological and optoelectronic aspects of YAlO3:Dy3+ doped nanocrystalline materials for NUV energized WLEDs

Structural and optical characterization of trivalent samarium-activated LaAlO3 nanocrystalline materials for solid-state lighting

VUV and UV photoluminescence of green emitting Sr2P2O7:Tb3+ phosphors for PDP applications

Ultraviolet, vacuum ultraviolet excited photoluminescence study of sol-gel derived CaAl4O7:Tb3+ green emitting phosphor

Luminescence studies of green emitting CaLa4Si3O13:Tb3+ phosphor for WLED and PDP applications

Green-emitting Tb3+ doped LaP3O9 phosphors for plasma display panel

UV/VUV excited photoluminescence of Tb3+ doped LaPO4 green emitting phosphors for PDP applications

Hoonil Jeong

Papers

VUV and UV photoluminescence of green emitting Sr2P2O7:Tb3+ phosphors for PDP applications

Ultraviolet, vacuum ultraviolet excited photoluminescence study of sol-gel derived CaAl4O7:Tb3+ green emitting phosphor

Luminescence studies of green emitting CaLa4Si3O13:Tb3+ phosphor for WLED and PDP applications

Green-emitting Tb3+ doped LaP3O9 phosphors for plasma display panel

UV/VUV excited photoluminescence of Tb3+ doped LaPO4 green emitting phosphors for PDP applications