Structural characterization of methanol substituted lanthanum halides

Boyle, Timothy J.; Ottley, Leigh Anna M.; Alam, Todd M.; Rodriguez, Mark A.; Yang, Pin; McIntyre, Sarah

doi:10.1016/j.poly.2010.02.027

Cited by 27 publications

(18 citation statements)

References 100 publications

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“…Our exploration of cerium-halide-based compounds has led to the synthesis of several new cerium-halide-containing materials exhibiting unique structural motifs that form via halide bridging between CeX n centers that are further modified via coordinated 16 15 (19) 13.6787 (15) 13.5954 (10) 18.0529 (18) 5.7157 (5) b/Å 21.1043 (13) 23.760 (2) 20.156 (2) 20.7910 (15) 26.421 (3) 11.3696 (9) c/Å 22.7005 (14) 26.488 (2) 21.192 (2) 22.1835 (15) 28.507 (3) 13.3140 (11) α/deg 68.3360 (10) 81.209 (2) 104.428 (2) 104.9620 (10) 90.00…”

Section: ■ Results and Discussionmentioning

confidence: 99%

New Family of Cerium Halide Based Materials: CeX₃·ROH Compounds Containing Planes, Chains, and Tetradecanuclear Rings

et al. 2012

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Six members of a new family of cerium-halide-based materials with promising scintillation behavior have been synthesized in single crystal form, and their crystal structures were determined. Specifically, these new compounds are [(CeCl(3))(7)(BuOH)(16)(H(2)O)(2)]·(BuOH)(2) (1), (CeBr(3))(14)(BuOH)(36) (2), [(CeCl(3))(7)(1-PrOH)(16)(H(2)O)(2)]·(1-PrOH)(2) (3), [(CeBr(3))(7)(1-PrOH)(18)]·(1-PrOH)(2) (4), [(CeCl(3))(6)(iBuOH)(15)]·(iBuOH)(2) (5), and CeCl(3)(sec-BuOH)(2)(H(2)O) (6). Additionally, the scintillation ability of compound 1 was established. The structures of these cerium-halide-based materials consist of catenated tetradecanuclear rings that arrange themselves into three distinct structural motifs which contain the largest lanthanide-based ring structures reported to date; the different motifs are obtained by involving specific alcohols during synthesis. Specifically, n-butanol and n-propanol lead to 1-D chains of tetradecanuclear rings, and iso-butanol leads to 2-D parquet-patterned sheets of rectangular tetradecanuclear rings, while sec-butanol results in a zigzag 1-D chain structure. One of the compounds, [(CeCl(3))(6)(iBuOH)(15)]·(iBuOH)(2), has been shown to scintillate with a light yield of up to 1920 photons/MeV, and due to the presence of protons, it should be capable of detecting high energy neutrons without the necessity of prior thermalization. Furthermore, it also appears to be the first cerium-based compound that scintillates in spite of the fact that water coordinates to two of the Ce(III) centers within the structure.

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Section: ■ Results and Discussionmentioning

confidence: 99%

New Family of Cerium Halide Based Materials: CeX₃·ROH Compounds Containing Planes, Chains, and Tetradecanuclear Rings

et al. 2012

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“…However, there are contradictory opinions about the stoichiometry of the equilibrium solid phase for the range Ho to Lu; it is either the isostructural monoclinic LnBr 3 ·6H 2 O or monoclinic LnBr 3 ·8H 2 O phase [ 9 – 12 ]. In the case of iodides, isostructural orthorhombic LnI 3 ·9H 2 O was identified for the lanthanide range of La to Er and isostructural monoclinic LnI 3 ·8H 2 O for the range of Tm to Lu [ 10 ]; however, different ranges of the solid solute existence were reported [ 11 , 12 ]. It is a well-known fact that structures and stoichiometries of YBr 3 and YI 3 hydrates resemble those typical for lanthanides, but crystals of ScBr 3 and ScI 3 hydrates are dissimilar compared with the corresponding lanthanide compounds.…”

Section: Solubility Data For Rare Earth Metal Bromides and Iodides Inmentioning

confidence: 99%

“…Likewise, the lighter Ln iodides dehydrate gradually according to the following reaction chain: whereas DyI 3 ·9H 2 O, HoI 3 ·9H 2 O, ErI 3 ·8H 2 O, TmI 3 ·8H 2 O, YbI 3 ·8H 2 O, and LuI 3 ·8H 2 O decompose to the anhydrous LnI 3 salts in one step according to Heiniö et al [ 22 ]. Crystallographic studies of the hydrates confirmed that they were isostructural: monoclinic P 2 1 / n for LnBr 3 ·8H 2 O (Ho–Lu), triclinic for LnBr 3 ·7H 2 O (La–Pr), monoclinic P 2/ n for LnBr 3 ·6H 2 O (Nd–Dy), orthorhombic Pmma for LnI 3 ·9H 2 O (La–Lu), unindexed (probably monoclinic) for LnI 3 ·8H 2 O (Tm–Lu), monoclinic P 2/ n for LnI 3 ·6H 2 O (La–Tb), and unindexed for LnI 3 ·3H 2 O (La–Nd) [ 10 , 12 , 22 – 24 ]. This detailed information is useful for calculation and depiction of the partial LnBr 3 –H 2 O and LnI 3 –H 2 O phase diagrams.…”

Section: Phase Diagrams At the Water-rich Sidementioning

confidence: 99%

Solubility of rare earth metal bromides and iodides in aqueous systems

2011

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The International Union of Pure and Applied Chemistry (IUPAC) project of collection, compilation, and critical evaluation of solubility data of bromides and iodides of the scandium group and all lanthanides in water and aqueous systems containing either halide acids, halide salts, or organic compounds is under preparation. As a result of their similarity to the chlorides, which were recently evaluated, the bromides and iodides in the lanthanide series should show some regularities in their solubility data. Unfortunately, the corresponding results show a large scatter when ordered according to the atomic number. Thus, it is complicated to select the best data for recommendation. Reasons for the inaccuracy of solubility measurements are outlined. In fact some solubility values of bromides predicted by correlation with chlorides seem to be more reliable than the experimental ones. As sufficient experimental data at various temperatures were available, the water-rich fragment of the LaBr3–H2O equilibrium phase diagram has been formed and depicted. It seems to be similar to the well-known LaCl3–H2O diagram. Several regularities, with respect to stoichiometry and solubility of compounds formed, were observed during investigations of the aqueous ternary systems. The complex iodides of various lanthanides display more regularities in their properties than the bromides do.Graphical abstract

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“…Boyles et al have observed similar trends within their series of methanol-substituted lanthanum halides obtaining monomeric and dimeric compounds. 23 Examining the differences in the bond distances of the bridging halides reveals that, in most cases, the polymeric chain with bound water has slightly shorter bridging halide bond distances than the dimers. Even though the alcohol and water ligands are neutral donors, their coordination greatly impacts the topological outcome of the structure.…”

Section: Structural Comparisons and Factorsmentioning

confidence: 99%

Crystal Growth, Structural Motifs, and Optical Properties of Molecular and Polymeric Cerium Halide Materials

Vaughn

Severance

Smith

et al. 2011

Crystal Growth & Design

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A series of seven compounds, Ce2Br6(CH3OH)8 (1), Ce2Br6(C2H5OH)8 (2), CeCl3(CH3OH)2(H2O) (3a), CeCl3(CH3OH)2(H2O) (3b), CeBr3((CH3)2CHOH)2(H2O) (4), Ce4Br10((CH3)2CHOH)10 (H2O)2(OH)2 (5), and CeCl3((CH3)2CHOH)2(H2O) (6) were synthesized via slow evaporation of CeBr3 or CeCl3 dissolved in an alcohol. This series structurally consists of two dimers, four polymeric chains, and one tetramer. The presence of water and/or hydroxide ions during synthesis profoundly affects the product structure by enhancing the formation of bridging halides, thus leading to polymeric rather than molecular structures. Each of the polymeric chains (3a, 3b, 4, 6) formed in response to the presence of water, to which cerium will preferentially coordinate over an alcohol. The tetrameric compound 5 formed in response to the presence of both water and hydroxide ions. These seven compounds, six of which are new compounds, demonstrate the diversity of these seemingly simple materials, which are described herein and were analyzed for their general trends in structure preferences and bond distances. The luminescent properties of compounds 1 and 2 are discussed and contrasted with that of CeBr3.

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Structural characterization of methanol substituted lanthanum halides

Cited by 27 publications

References 100 publications

New Family of Cerium Halide Based Materials: CeX₃·ROH Compounds Containing Planes, Chains, and Tetradecanuclear Rings

New Family of Cerium Halide Based Materials: CeX₃·ROH Compounds Containing Planes, Chains, and Tetradecanuclear Rings

Solubility of rare earth metal bromides and iodides in aqueous systems

Crystal Growth, Structural Motifs, and Optical Properties of Molecular and Polymeric Cerium Halide Materials

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Structural characterization of methanol substituted lanthanum halides

Cited by 27 publications

References 100 publications

New Family of Cerium Halide Based Materials: CeX3·ROH Compounds Containing Planes, Chains, and Tetradecanuclear Rings

New Family of Cerium Halide Based Materials: CeX3·ROH Compounds Containing Planes, Chains, and Tetradecanuclear Rings

Solubility of rare earth metal bromides and iodides in aqueous systems

Crystal Growth, Structural Motifs, and Optical Properties of Molecular and Polymeric Cerium Halide Materials

Contact Info

Product

Resources

About

New Family of Cerium Halide Based Materials: CeX₃·ROH Compounds Containing Planes, Chains, and Tetradecanuclear Rings

New Family of Cerium Halide Based Materials: CeX₃·ROH Compounds Containing Planes, Chains, and Tetradecanuclear Rings