Transition probabilities of europium in phosphate glasses

Reisfeld, Renata; Velapoldi, R. A.; Boehm, L.; Ish-Shalom, M.

doi:10.1021/j100695a012

Cited by 65 publications

(38 citation statements)

References 8 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…1a, this line is asymmetrically broadened in unpoled NBT-6BT:Eu suggesting two closely spaced lines of nearly equal intensity (marked with an arrow). Earlier, extensive broadening of the 5 D 0  7 F 0 line have been reported in Eu doped calcium diborate, silicate, germinate and phosphate glasses due to a large number of sites of same local symmetry (C s ) but with slightly varying crystal field strengths [23,24]. In our case, the slightly different crystal field strengths can arise from the different local chemical environment around Eu +3 formed by different configurations of Na and Bi and Ba [25,26], along with their respective local polar displacements [27].…”

mentioning

confidence: 96%

Tuning Photoluminescence Response by Electric Field in Electrically Soft Ferroelectrics

2016

View full text Add to dashboard Cite

We show that an electrically soft ferroelectric host can be used to tune the photoluminescence (PL) response of rare-earth emitter ions by external electric field. Photoluminescence (PL) property of lanthanide ions is a subject of continuing interest because of its enormous applications in lighting industry, Laser, fiber optics telecommunications, biological assaying and medical imaging [1,2]. The most common strategy prevalent among experimentalists is to investigate the PL response/mechanisms by placing the luminescent centers in different kinds of host matrices or ligand environments. Among others, crystallographic symmetry of the host crystal is one of the important factors that influences PL emission in solids [3]. As such, temperature, pressure, and compositional modifications which can induce crystallographic transformations can, as well, affect the PL response. In general, pressure induced phase transformations in inorganic materials occur at Giga Pascal pressure ranges which is not easily achievable under ordinary conditions. From a device point of view, it is always desirable to tune/control properties around the ambient temperature and pressure conditions. In principle, it can be argued that if, apart from temperature and pressure, other control parameters are available to change the crystal structure, this parameter can as well tune different types of structure-sensitive properties, including PL. Such a scenario does exist in electrically and elastically soft ferroelectrics in the proximity of a ferroelectric instability. The electromechanical softness of the lattice, in conjunction with the strong coupling of polarization with crystal structure, makes such systems amenable to field induced structural transformation [4][5][6][7][8][9][10][11][12][13]. The consequent change in the crystal field parameters is expected to affect the PL response of doped emitter ions, such as the rare earth ions, if they are embedded in such a ferroelectric host. Apart from serving as probes to understand the local structural changes due to external influences such as temperature, pressure, electric field, etc., rare-earth doping of soft ferroelectrics can form a new class of multifunctional materials, which may be termed as "luminescent-piezoelectric", based on which new applications can be envisaged. With this as the motivation, and to demonstrate the proof of this concept, we have studied the electric field effect

show abstract

mentioning

confidence: 96%

Tuning Photoluminescence Response by Electric Field in Electrically Soft Ferroelectrics

2016

View full text Add to dashboard Cite

show abstract

“…[19] Here the R value is about 9.9, indicating that the local surrounding observed in our sample is highly asymmetric if taking into account that R value reported for europiumA C H T U N G T R E N N U N G (III) ions in aqueous solution, in which they are directly coordinated to 8-9 water molecules, is 0.43. [20] Coating the silica shell on microporous hybrid material 1 following the procedure reported in reference [6] produces the core-shell hybrid material 2. The formation of the silica shell was obsereved by SEM (Figure 2).…”

Section: Resultsmentioning

confidence: 99%

Surface Modification and Functionalization of Microporous Hybrid Material for Luminescence Sensing

Cheng

Wang

et al. 2010

Chemistry A European J

View full text Add to dashboard Cite

We report here on the preparation of novel luminescent core-shell material by initial coating with polyelectrolytes and subsequent with a silica shell on the lanthanide complexes loaded zeolite L microcrystals. Lanthanide complexes loaded zeolite L was prepared by insertion of 2-thenoyltrifluoroacetone (TTA) into the nanochannels of zeolite crystals by gas diffusion of TTA to Eu(3+) exchanged zeolite L, coating a silica shell on the lanthanide complexes loaded zeolite L resulted to the novel luminescent core-shell material. The luminescent core-shell material was further functionalized with silylated terbium(III) complex and the obtained material was used as the luminescence sensing of dipicolinic acid (DPA), which is a major constituent of many pathogenic spore-forming bacteria.

show abstract

“…In a cube made of phosphate tetrahedra in which the phosphorus-oxygen distance is 1.57 A and the oxygen-oxygen distance is 2.56 A, the rare-earth oxygen distance is 2.22 A. It should be realized that in reality the symmetry is lower than cubic, and for the particular cases studied it was found to be of Cs symmetry Eu 3 + in phosphate glass, [40] and C2 for Tm3+ is phosphate and borate glasses [39]. As a result of this lower symmetry, forced electric dipole transitions become possible and absorption and fluorescence is observed.…”

Section: The Rare-earth-doped Glassesmentioning

confidence: 86%

“…,-- b = repulsion coefficient: r= distance between active ion and nearest anion; n=4 to 1O~_ It was shown in a series of papers by Reisfeld et al [36][37][38][39][40], that the behavior of rare earths in glasses is similar to that of rare earths in inorganic crystals of low symmetry except for inhomogeneous broadening of the spectra due to a multiplicity of rare-earth sites in glasses. According to our theory [39] a rare·earth ion occupies a center of a distorted cube comprised of four tetrahedra of borate, phosphate or silicate.…”

Section: The Rare-earth-doped Glassesmentioning

confidence: 99%

Inorganic ions in glasses and polycrystalline pellets as fluorescence standard reference materials

Reisfeld¹

1972

J. RES. NATL. BUR. STAN. SECT. A.

Self Cite

View full text Add to dashboard Cite

The absorption and fluorescence of inorgan ic glasses and polycrystalline disks doped by heavy metal ions is discuss ed , and their use as fluoresce nce stand ard s is evaluated. The advantages of the glass standards over other media is summarized.The glass standards are divided into two groups (1) glasses doped by trivale nt rare earths such as Gd3 +, Tb3 +, Eu3 +, Sm3 +, and Tm3+ which have narrow band optical s pectra as a result of intraconfig~rational transitions, and (2) glasses and polycrystalline disks doped by ions s uch as Tl+, Pb 2 +, Ce 3 +, and Cu + whi ch have broad spectral bands since th e optical spectra originate from interconfigurationally allowed transitions. Optical and physical parameters , including matrix effects, quantum efficiencies, decay characteristics, Stokes' shifts and spin-orbit versus orbit-lattice interaction s due to the different trans itions wi ll be discussed.Group (1) glasses are suitable for use as standards where a narrow well-defined fluorescence range is required, and group (2) glasses are suitable for use as standards whenever a substance with a wide range of fluorescen ce is measured. Special em phasis will be placed on energy transfer between donor and acceptor ions.

show abstract

Transition probabilities of europium in phosphate glasses

Cited by 65 publications

References 8 publications

Tuning Photoluminescence Response by Electric Field in Electrically Soft Ferroelectrics

Tuning Photoluminescence Response by Electric Field in Electrically Soft Ferroelectrics

Surface Modification and Functionalization of Microporous Hybrid Material for Luminescence Sensing

Inorganic ions in glasses and polycrystalline pellets as fluorescence standard reference materials

Contact Info

Product

Resources

About