Thermodynamic properties of the pseudo-binary CsCl–LnCl3   (Ln=Ce,Pr,Nd) systems

Kapała, Jan; Rutkowska, Iwona

doi:10.1016/j.calphad.2004.09.005

Cited by 10 publications

(4 citation statements)

References 16 publications

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“…The entropy of mixing of the liquid CsCl-PrCl 3 system is close to zero. This is consistent with the results obtained for similar systems [4]. Taking into account the above considerations the authors invite question: Do results obtained for CsCl-PmCl 3 system are connected with instability of Pm?…”

Section: Discussionsupporting

confidence: 91%

Prediction of the thermodynamic data of the pseudobinary alkali halide–lanthanide halide condensed systems

Kapała

Bochynska

Broczkowska

et al. 2008

Journal of Alloys and Compounds

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Section: Discussionsupporting

confidence: 91%

Prediction of the thermodynamic data of the pseudobinary alkali halide–lanthanide halide condensed systems

Kapała

Bochynska

Broczkowska

et al. 2008

Journal of Alloys and Compounds

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“…[9][10][11] The CsCe 2 Cl 7 with a density of 3.6 g cm À3 can reach a gamma-ray excited light yield of 26 000 photons per MeV, but a 50% higher light yield is achieved in CsCe 2 Br 7 with a higher density of 4.0 g cm À3 . The phase diagrams of CsCe 2 Cl 7 12 and CsCe 2 Br 7 13,14 indicate that they both melt congruently. Recently, the crystal structure refinement revealed that CsCe 2 Cl 7 crystallizes in the monoclinic space group P112 1 /b.…”

Section: Introductionmentioning

confidence: 96%

Crystal structure, electronic structure, temperature-dependent optical and scintillation properties of CsCe₂Br₇

Shi

Chakoumakos

et al. 2015

J. Mater. Chem. C

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CsCe 2 Br 7 is a self-activated inorganic scintillator that shows promising performance, but the understanding of the important structure-property relationships is lacking. In this work, we conduct a comprehensive study on CsCe 2 Br 7 . The crystal structure of CsCe 2 Br 7 is refined using single crystal X-ray study for the first time. It crystallizes into the orthorhombic crystal system with Pmnb space group. Its electronic structure is revealed by density functional theory (DFT) calculations. Two cerium emission centers are identified and the energy barriers related to the thermal quenching to 4f ground states of Ce 3+ for these two Ce centers are evaluated. CsCe 2 Br 7 single crystal has better light yield and energy resolution than CsCe 2 Cl 7 , but with an additional slow decay component of 1.7 ms. The existence of a deep trap with a depth of 0.9 eV in CsCe 2 Cl 7 contributes to its higher afterglow level in comparison to that of CsCe 2 Br 7 . The most possible point defects in CsCe 2 Cl 7 and CsCe 2 Br 7 are proposed by considering the vapour pressure in the growth atmosphere upon melting point.ionic activators (in particular Bi 3+ , Ce 3+ and Eu 2+ ), is a constituent of the crystal, for example CaWO 4 and Self-activated single crystals of CsCe 2 X 7 (X = Cl, Br) were developed in 2010. 9-11 The CsCe 2 Cl 7 with a density of 3.6 g cm À3 can reach a gamma-ray excited light yield of 26 000 photons per MeV, but a 50% higher light yield is achieved in CsCe 2 Br 7 with a higher density of 4.0 g cm À3 . The phase diagrams of CsCe 2 Cl 7 12 and CsCe 2 Br 7 13,14 indicate that they both melt congruently. Recently, the crystal structure refinement revealed that CsCe 2 Cl 7 crystallizes in the monoclinic space group P112 1 /b. 15 However, despite the fact that the CsCe 2 Br 7 single crystal showed more promising scintillation properties, several fundamental questions, including structureproperty relationship, are still not understood: (i) the crystal structure and electronic structure; (ii) temperature dependent luminescent behaviors; (iii) the scintillation property comparisons between CsCe 2 Cl 7 and CsCe 2 Br 7 , including non-proportionality and afterglow; (iv) the trapping effect of point defects and their possible origins. All these questions lead us to carry out an in-depth study of CsCe 2 Br 7 . The paper is organized as follows. Firstly, the crystal

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“…The growing interest in the NaBr-DyBr 3 system is illustrated by recent studies of their Z. Varga · M. Hargittai ( ) Structural Chemistry Research Group of the Hungarian Academy of Sciences at Eötvös University, P.O.Box 32, H-1518, Budapest, Hungary e-mail: hargitta@chem.elte.hu mass spectra [5] and phase diagrams [6]. Mass spectrometry has proved to be the major experimental tool to study these systems [4,5,[7][8][9][10][11][12][13][14][15][16][17], yielding information about the composition and thermochemical properties of the systems found in the vapor. Modeling the processes in the high-temperature lamp facilitates improving lamp designs.…”

Section: Introductionmentioning

confidence: 99%

The NaDyBr4 complex; its molecular structure and thermodynamic properties

Varga

Hargittai

2006

Struct Chem

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The molecular geometry, vibrational frequencies, relative stabilities, and some thermodynamic properties of different isomers of the NaDyBr 4 complex were determined by computation. We investigated, to our knowledge for the first time for such a complex, the possible effect of the partially filled 4f orbitals on the molecular properties of an MLnX 4 complex by using a "small core" effective core potential of the Stuttgart group. The tridentate complex, with three Na-Br bridges, was found to be the ground-state structure with the bidentate one only about 4-6 kJ/mol higher in energy. The relative abundance of these isomers changes with temperature and at the high-temperature conditions of a metal halide lamp the bidentate isomer is the more abundant isomer.

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Thermodynamic properties of the pseudo-binary CsCl–LnCl3 (Ln=Ce,Pr,Nd) systems

Cited by 10 publications

References 16 publications

Prediction of the thermodynamic data of the pseudobinary alkali halide–lanthanide halide condensed systems

Prediction of the thermodynamic data of the pseudobinary alkali halide–lanthanide halide condensed systems

Crystal structure, electronic structure, temperature-dependent optical and scintillation properties of CsCe₂Br₇

The NaDyBr4 complex; its molecular structure and thermodynamic properties

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Thermodynamic properties of the pseudo-binary CsCl–LnCl3 (Ln=Ce,Pr,Nd) systems

Cited by 10 publications

References 16 publications

Prediction of the thermodynamic data of the pseudobinary alkali halide–lanthanide halide condensed systems

Prediction of the thermodynamic data of the pseudobinary alkali halide–lanthanide halide condensed systems

Crystal structure, electronic structure, temperature-dependent optical and scintillation properties of CsCe2Br7

The NaDyBr4 complex; its molecular structure and thermodynamic properties

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Crystal structure, electronic structure, temperature-dependent optical and scintillation properties of CsCe₂Br₇