Preparation of BaBi1/2Sb1/2O3 from Ba(COO)2·0.5H2O and Sb(COO)2(OH) oxalates and Bi2O3 oxide

Корзун, Б. В.; Schorr, Susan; Schmitz, W.; Fadzeyeva, A. A.; Kommichau, G.; Bente, K.

doi:10.1016/j.jcrysgro.2004.12.136

Cited by 3 publications

(4 citation statements)

References 7 publications

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“…They react to ternary compounds like ZnSb2O6, at about the same temperatures as the mixtures of the binary oxides (1073 K [22]) do, way above the decomposition temperature of SbC2O4OH. Similar behavior was observed for the reaction of SbC2O4OH, with barium oxalate hydrate and bismuth oxide to BaBi1/2Sb1/2O3 [9]. The advantage of a low decomposition temperature is thus only an apparent one for the precursor-based synthesis of antimonates.…”

Section: Discussionsupporting

confidence: 65%

“…It decomposes within one step at 563 K to antimony(III) oxide [7,8]. SbC 2 O 4 OH can be used for the preparation of antimony containing compounds, i.e., mixed crystal oxides such as BaBi 1/2 Sb 1/2 O 3 [9]. The low decomposition temperature, simple synthesis and stable composition seem to be attractive properties for usage as a precursor for antimony-based materials.…”

Section: Introductionmentioning

confidence: 99%

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Crystal Structure and Thermal Behavior of SbC2O4OH and SbC2O4OD

et al. 2020

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The order of OH groups in the crystal structure of SbC2O4OH, a potential precursor in the synthesis of ternary oxides, was debated. Neutron diffraction on the deuteride SbC2O4OD revealed disordered OD groups with half occupation for deuterium atoms on either side of a mirror plane (SbC2O4OD at T = 298(1) K: Pnma, a = 582.07(3) pm, b = 1128.73(5) pm, c = 631.26(4) pm). O–H stretching frequencies are shifted by a factor of 1.35 from 3390 cm−1 in the hydride to 2513 cm−1 in the deuteride as seen in infrared spectra. SbC2O4OH suffers radiation damage in a synchrotron beam, which leaves a dark amorphous residue. Thermal decomposition at 564 K yields antimony oxide, carbon dioxide, carbon oxide, and water in an endothermic reaction. When using SbC2O4OH as a precursor in reactions, however, ternary oxides are only formed at much higher temperatures.

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Section: Discussionsupporting

confidence: 65%

Section: Introductionmentioning

confidence: 99%

Crystal Structure and Thermal Behavior of SbC2O4OH and SbC2O4OD

et al. 2020

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“…6 For Ce-oxalate, the H 2 O loss occurred at 100-190 • C and further decomposition into CeO 2 was presented by the exothermic peak at 295 • C. 7 Y-oxalate sample presented H 2 O loss at 130-246 • C and decomposition into Y 2 O 3 at 400-687 • C.…”

Section: Resultsmentioning

confidence: 97%

Synthesis of BaCeO3 and BaCe0.9Y0.1O3−δ from mixed oxalate precursors

Oliveira

Hafsaoui

Hochepied

et al. 2007

Journal of the European Ceramic Society

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“…The white solid was washed several times with de-ionized water and dried at 110 °C for 3 h. A 96% yield was obtained. The compound has been prepared previously by reaction of oxalic acid dihydrate and SbCl 3 (Korzun et al , 2005; Karlov et al , 1983; Ambe, 1975).…”

Section: Methodsmentioning

confidence: 99%

Crystal structure of antimony oxalate hydroxide, Sb(C₂O₄)OH

Kaduk¹,

Toft²,

Golab³

2010

Powder Diffr.

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The crystal structure of Sb͑C 2 O 4 ͒OH has been solved by charge flipping in combination with difference Fourier techniques using laboratory X-ray powder data exhibiting significant preferred orientation and refined by the Rietveld method. The compound crystallizes in Pnma with a = 5.827 13͑3͒, b = 11.294 48͑10͒, c = 6.313 77͑3͒ Å, V = 415.537͑5͒ Å 3 , and Z = 4. The crystal structure contains pentagonal pyramidal Sb 3+ cations, which are bridged by hydroxyl groups to form zigzag chains along the a axis. Each oxalate anion chelates to two Sb in approximately the ab plane, linking the chains into a three-dimensional framework. The H of the hydroxyl group is probably disordered in order to form stronger more-linear hydrogen bonds. The highest energy occupied molecular orbitals are the Sb 3+ lone pairs. The structure is chemically reasonable compared to other antimony oxalates and to Bi͑C 2 O 4 ͒OH.

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Preparation of BaBi1/2Sb1/2O3 from Ba(COO)2·0.5H2O and Sb(COO)2(OH) oxalates and Bi2O3 oxide

Cited by 3 publications

References 7 publications

Crystal Structure and Thermal Behavior of SbC2O4OH and SbC2O4OD

Crystal Structure and Thermal Behavior of SbC2O4OH and SbC2O4OD

Synthesis of BaCeO3 and BaCe0.9Y0.1O3−δ from mixed oxalate precursors

Crystal structure of antimony oxalate hydroxide, Sb(C₂O₄)OH

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Preparation of BaBi1/2Sb1/2O3 from Ba(COO)2·0.5H2O and Sb(COO)2(OH) oxalates and Bi2O3 oxide

Cited by 3 publications

References 7 publications

Crystal Structure and Thermal Behavior of SbC2O4OH and SbC2O4OD

Crystal Structure and Thermal Behavior of SbC2O4OH and SbC2O4OD

Synthesis of BaCeO3 and BaCe0.9Y0.1O3−δ from mixed oxalate precursors

Crystal structure of antimony oxalate hydroxide, Sb(C2O4)OH

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Crystal structure of antimony oxalate hydroxide, Sb(C₂O₄)OH