2007
DOI: 10.1002/pssc.200673787
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Nanocrystalline SrTiO3:Eu3+ and BaTiO3:Eu3+: fluorescence spectroscopy and optical studies of structural phase transitions

Abstract: The results of optical studies of Eu 3+ ions doped nanocrystalline materials which undergo structural phase transitions: SrTiO 3 :Eu 3+ and BaTiO 3 :Eu 3+ are presented. Nanocrystalline SrTiO 3 and BaTiO 3 samples with crystallite sizes about 25 -50 nm were produced by the sol-gel process. The EuF n fluorescence spectra were studied. Time-resolved fluorescence spectra enabled to separate different kinds of Eu 3+ centers in BaTiO 3 samples. Fluorescence spectroscopy of probe Eu 3+ ions was used to detect the st… Show more

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Cited by 15 publications
(12 citation statements)
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“…The substitution of Sr 2+ ions by Eu 3+ can induce a charge decompensation as has been reported [14]; this result can distort the crystalline lattice which could enhance the luminescence intensity of SrTiO 3 :Eu 3+ because the interatomic 4f-4f Eu 3+ forbidden transitions are more probable in lattices with no inversion of symmetry [17]. Thus, the crystalline lattice is distorted by the charge decompensation and by the difference between the atoms sizes of the Eu 3+ (1.087Å) and Sr 2+ (1.44Å); this has been observed in several perovskite systems [14][15][16][22][23][24]. A measure of the distortion of a perovskite-type ABO 3 lattice can be determined by using the Goldsmith tolerance factor ( ) that depends on the ionic radii , , and of the perovskite ABO 3 structure [24] and is given by the following equation:…”
Section: Resultsmentioning
confidence: 94%
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“…The substitution of Sr 2+ ions by Eu 3+ can induce a charge decompensation as has been reported [14]; this result can distort the crystalline lattice which could enhance the luminescence intensity of SrTiO 3 :Eu 3+ because the interatomic 4f-4f Eu 3+ forbidden transitions are more probable in lattices with no inversion of symmetry [17]. Thus, the crystalline lattice is distorted by the charge decompensation and by the difference between the atoms sizes of the Eu 3+ (1.087Å) and Sr 2+ (1.44Å); this has been observed in several perovskite systems [14][15][16][22][23][24]. A measure of the distortion of a perovskite-type ABO 3 lattice can be determined by using the Goldsmith tolerance factor ( ) that depends on the ionic radii , , and of the perovskite ABO 3 structure [24] and is given by the following equation:…”
Section: Resultsmentioning
confidence: 94%
“…The Sr 2+ or Eu 3+ ions are surrounded by eight TiO 6 octahedrons in the SrTiO 3 :Eu 3+ matrix; thus, the TiO 6 anions should be distorted in the perovskite structure SrTiO 3 :Eu 3+ by the doping effect of Eu 3+ ; in consequence, the sites where the Eu 3+ ions are located within the crystal lattice of STO lack symmetry. This is beneficial for our powders because the photoluminescence properties are enhanced [14][15][16]. The imbalance of the crystalline structure can also be observed by a shift of the diffraction peaks in the XRD patterns.…”
Section: Resultsmentioning
confidence: 97%
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“…[6], see [7] for the spectra of our samples) in the temperature range, which includes the C 4v -O h phase transition temperature and where the SHG hysteresis was observed [3]. This SHG hysteresis (which is not related to the presence of impurity ions) is due to ordering in the ensemble of dipole ferroelectric nanoparticles [3].…”
Section: Fluorescence Lifetimes: Batio 3 :Eu 3+mentioning
confidence: 85%