Kristallstruktur und Phasenumwandlungen von As(CH3)4I

Crystal Structure and Phase Transitions of As(CH₃)₄I The crystal structure of α-As(CH₃)₄I at room temperature was determined using single crystal data: cubic, space group Pa3 , a = 1 198.0(2) pm. Therefore α-As(CH₃)₄I displays a novel crystal structure, which is not comparable to known AB-Typ structures with respect to the arrangement of anions and the baricenters of the complex cations. Differential thermal analysis showed three phase transitions at 103, 175 and 215°C. The lattice parameters of the high temperature phases (temperature dependent Guinier measurements) are: β-As(CH₃)₄I (tetragonal): a = 845.2(2) pm, c = 615.0(2) pm; γ-As(CH₃)₄I (hexagonal): a = 737.7(2) pm, c = 1 082.2(3) pm; and to δ-As(CH₃)₄I (hexagonal): a = 705.8(2) pm, c = 1 147(1) pm. β-and γ-As[(CH₃)]₄I are isotypic to N(CH₃)₄Cl and As(CH₃)₄Br, respectively.     

Synthese,Kristallstruktur und magnetische Eigenschaften von TbAl3Cl12

Synthesis, Crystal Structure, and Magnetic Properties of TbAl₃Cl₁₂ TbAl₃Cl₁₂ was synthesized and the crystal structure was determined from single crystal X‐ray diffraction data for the first time. The compound crystallizes trigonally in space group P3₁12 with a = 1049.8(1) and c = 1567.3(2) pm. Terbium cations are located in quadratic antiprisms of chloride anions. Magnetic measurements were performed to study the interactions between Tb³⁺ and Cl^–. Magnetic data were interpreted by ligand field calculations applying the angular overlap model.     

Zur Kristallstruktur von MnF3 und MnPtF6

On the Crystal Structure of MnF₃ and MnPtF₆ Single crystal investigations of MnF₃ (rubyred) confirmed the crystal structure based on powder data [2]: monoclinic, space group C 2/c?C (No. 15) with a = 892.02 pm, b = 504.72 pm, c = 1 347.48 pm, β = 92.64° with Z = 12. The corresponding determination of the crystal structure of MnPtF₆, yellow, confirmed the unit cell [3] with a = 510.47 pm, c = 1 421.0 pm and γ = 120°, Z = 3 space group R 3 -C (No. 148). For both compounds detailed parameters respectively interatomic distances have been obtained.     

Synthese und Kristallstruktur von Cs3Y7Se12

Synthesis and Crystal Structure of Cs₃Y₇Se₁₂ The oxidation of yttrium metal with selenium in the presence of CsCl (7 d, 700°C, evacuated silicia tubes) results in the formation of pale yellow, lath-shaped single crystals of Cs₃Y₇Se₁₂. The crystal structure (orthorhombic, Pnnm, Z = 2, a = 1272.8(3), b = 2627.7(5), c = 413.32(8) pm) consists of edge- and vertex-connected [YSe₆] octahedra forming a rocksalt-related network [Y₇Se₁₂]^3?. One-dimensional infinite channels along [001], apt to take up extra cations, provide coordination numbers of 6 and 7 + 1, respectively, for two crystallographically different Cs⁺.     

[Li(12-Krone-4)]Cl: Kristallstruktur und IR-Spektrum

[Li(12-Crown-4)]Cl: Crystal Structure and I.R. Spectrum Colourless single crystals of [Li(12-crown-4)]Cl were obtained from acetonitrile solutions of LiCl in the presence of 12-crown-4. They were characterized by i. r. spectroscopy as well as by an X-ray structure determination. Space group P4/n, Z = 2, 1 080 observed unique reflections, R = 0.034. Lattice dimensions at ?50°C; a = 837.8(5), c = 752.0(2) pm. [Li(12-crown-4)]Cl forms ion pairs with tetragonal symmetry and bond lengths Li? O of 212.8 pm and Li? Cl of 229.0 pm.     

Synthese und Kristallstruktur von LiHSO4

Synthesis and Crystal Structure of LiHSO₄ Single crystals of the new compound LiHSO₄ are synthezised from the system Lithiumsulfate/Sulfuric acid. The up to day not determined structure of the title compound is monoclinic, space group P2₁/c with the lattice constants a = 5.234(2), b = 7.322(1) and c = 8.363(1) Å, b? = 90.02(2)°. The volume of the unit cell has been determined to V = 320.5 ų, the number of formula units to Z = 4 and the density to D_x = 2.156 g cm^?3. There are crystallographically identical SO₃(OH)- and LiO₄-tetrahedra in the structure. Every tetraheda is linked to four different tetrahedra of the other sort. Two neighboured LiO4 terahedra form a common edge. In that way layers are formed running parallel the yz-plane. These layers are connected over hydrogen bonds.     

Darstellung und Kristallstruktur von Rb2Ni3Se4

Preparation and Crystal Structure of Rb₂Ni₃Se₄ The compound Rb₂Ni₃Se₄ was synthesized by heating a mixture of rubidium carbonate, nickel and selenium at 850°C in an atmosphere of hydrogen. The compound has a golden lustre and crystallizes with the K₂Pd₃S₄-type structure; a = 10.555(3) Å, b = 27.588(6) Å, c = 6.031(6) Å, Z = 8, Fddd (No. 70). The structure can be described as a stacking of layers of the composition Rb₂Ni₃Se₄ with a stacking sequence abcd. The electrostatic part of lattice energy (MAPLE) will be discussed for compounds of the compositions A₂M₃X₄ (A K, Rb, Cs; M Ni, Pd, Pt and X S, Se).     

Synthese und Kristallstruktur von Hydronium-tris-ethylendiamin-cobalt(rhodium)-μ-trichloro-nonachlorotrirhenat(II)-chlorid,H3O[MEn3][Re3Cl12]Cl (M=Co,Rh)

Synthesis and Crystal Structure of Hydronium-tris-ethylenediamine-cobalt(rhodium)-μ-trichloro-nonachlorotrirhenate(III)-chloride, H₃O[MEn₃][Re₃Cl₁₂]Cl (M=Co, Rh) The chlorides H₃O[MEn₃][Re₃Cl₁₂]CI (M = Co, 1 ; Rh, 2 ) crystallize from hydrochloric acid solutions of ReCl₃ and MEn₃ · 3H₂O as deep red hexagonal columns. They are isotypic and crystallize with the hexagonal system (P6 , Z = 1; 1: a = 1010.87(3); c = 794.30(4) pm, R = 0.023, R_w = 0.016; 2: a = 1018.58(3); c = 794.74(4) pm, R = 0.026, R_w = 0.018). The anions [Re₃Cl₁₂]^3? are connected via H₃O₊ cation (C.N. 3). The large channels that run in the [001] direction contain, alternatively, the cations [MEn₃]³⁺ and the lonesome Cl^?-anions     

Synthese und Kristallstruktur von CaBiVO5

Synthesis and Crystal Structure of CaBiVO₅ Single crystals of the hitherto unknown compound CaBiVO₅ were prepared and investigated by X-ray work. It crystallizes with orthorhombic symmetry, space group D? Pbca, a = 11.2022, b = 5.4283, c = 15.5605 Å, Z = 8. The crystal structure is characterized by layers of the edge-linked CaO₇ polyhedra, isolated VO₄ tetrahedra and an asymmetric surrounding of Bi³⁺ by oxygen.     

Synthese und Kristallstruktur von KMgCu4V3O13

Synthesis and Crystal Structure of KMgCu₄V₃O₁₃ . Single crystals of KMgCu₄V₃O₁₃ were prepared by supercooled melts. It crystallizes with monoclinic symmetry space group C–P2₁/m (Nr. 11), unit cell dimensions: a = 10.7144 Å, b = 6.0282 Å, c = 8.3365 Å, β = 98.075°, Z = 2. The crystal structure is closely related to the BaMg₂Cu₈O₆O₂₆ type. Cu²⁺ occurs in an unusual trigonal bipyramidal coordination.     

Reaktion von Chlornitrat mit CF3I: Isolierung von Trifluormethylchloriodnitrat CF3I(Cl)ONO2 und Kristallstruktur von Trifluormethylioddinitrat CF3I(ONO2)2

Reaction of Chlorine Nitrate with CF₃I: Isolation of Trifluormethylchloroiodinenitrate CF₃I(Cl)ONO₂ and the Crystal Structure of Trifluormethyliodinedinitrate CF₃I(ONO₂)₂ CF₃I reacts with ClONO₂ to Iodine(III)-compounds. After an addition CF₃I(Cl)ONO₂ is isolated and characterized by vibrational spectra. With surplus ClONO₂ it is formed CF₃I(ONO₂)₂. CF₃I(ONO₂)₂ crystallizes monoclinic in the space group P2₁/c with the cell parameters a = 1 024.3(6) pm, b = 873.5(6) pm, c = 873.4(6) pm and Z = 4. We measered following bonding distances: I? O: 207.3(3) and 220.8(2) pm, I? C: 221.1(4) pm and N? O: from 119.1(4) to 141.5(3) pm. Through an intermolecular I ··· O-contact the central iodine becomes a distorted plane geometry.     

Darstellung,Kristallstruktur und Eigenschaften von Kaliumhydrogencyanamid

Preparation, Crystal Structure, and Properties of Potassium Hydrogen Cyanamide For the preparation of KHCN₂ melamine has been reacted with potassium amide in liquid ammonia. After evaporation of the solvent the resulting solid has been transformed at 210°C. KHCN₂ (P2₁2₁2₁, a = 708.7(2), b = 909.0(2), c = 901.4(2) pm, Z = 8, R = 0.039, wR = 0.016) is yielded as a coarse crystalline product. In the solid K⁺ and HCN ions occur. As expected two significantly differing bond-distances C? N (117.3(5) pm) and HN? C (128.7(5) pm) have been found in the anion. According to IR-spectroscopy a non linear group N? C? N (174.4(4)°) is observed.     

Nitridsulfidchloride der Lanthanide: III. Synthese und Kristallstruktur von Pr5N3S2Cl2

Nitride Sulfide Chlorides of the Lanthanides. III. Synthesis and Crystal Structure of Pr₅N₃S₂Cl₂ By reacting praseodymium with sulfur, sodium azide and praseodymium trichloride in sealed, evacuated silica tubes (850°C, 7 d), the nitride sulfide chloride Pr₅N₃S₂Cl₂ is obtained in case of a 4:2:1:1 molar ratio of the reactants (Pr:S:NaN₃:PrCl₃). A slight excess of trichloride or the addition of NaCl as a flux supports the yield of brownish red, rod-shaped transparent crystals which prove to be stable against hydrolysis. The crystal structure (monoclinic, C2/m (no. 12), a = 1540.2(1), b = 400.92(3), c = 1656.3(1) pm, β = 101.24(1)°, Z = 4, R = 0.039, R_w = 0.028) was determined by means of X-ray single crystal data. Thus five crystallographically different cations (Pr³⁺) are present which with three distinct kinds of nitride anions (N^3?) build up two types of translationally commensurate chains from interconnected [NPr₄] tetrahedra. With an additional edge per “chain-link” in chain I, two single chains [NPr_3/3^ePr_1/1^t]³⁺ (?[NPr₂]³⁺) of cis-edge connected [NPr₄] tetrahedra (known from the Sm₄N₂S₃-type structure) are condensed into the double chain [(N1){(Pr1)_(2+2)/(2+2)^e,e(Pr2)_(2+1)/(2+1)^e,v}(N2)(Pr3)_1/1^t]³⁺ (?[N₂Pr₃]³⁺). Chain II consists of two single chains [NPr_2/2^vPr_2/1^t] ⁶⁺ (?[NPr₃]⁶⁺) of vertex-connected [NPr₄] tetrahedra (known from the Sm₃NS₃-type structure), which are condensed to the double chain [(N3)(Pr4)_2/2^e(Pr5)_2/2^v]³⁺ (?[NPr₂]³⁺) via an additional edge per “chain-link” too. Both types of chains are bundled along [010] like a closest packing of rods. Four crystallographically different but by X-ray diffraction indistinguishable anions S^2? and Cl^? hold both cationic double chains together and also adjust the charge balance in a molar ratio of 1 : 1.     

Darstellung und Kristallstruktur von NaBi2AuO5

Synthesis and Crystal Structure of NaBi₂AuO₅ NaBi₂AuO₅ was obtained by hydrothermal reaction of ‘Bi₂O₅’, Au₂O₃ · 2H₂O and saturated aqueous NaOH solution at temperatures from 300 to 600°C and oxygen pressure from 3 × 10⁸ to 6 × 10⁸ Pa for the first time. The crystal structure (P4 b2; a = 1 220.02(6) pm; b = 386.68(3) pm; Z = 4; R_w = 0.022) consists of bisphenoidic distorted AuO₄ groups, which are stacked in c-direction. They are connected by square pyramidal BiO₅ units. Sodium is occupying holes within the Au/Bi/O framework thus formed.     

Darstellung,Kristallstruktur und spektroskopische Charakterisierung von P4O6Se3

Synthesis, Crystal Structure, and Spectroscopic Characterization of P₄O₆Se₃ P₄O₆Se₃ has been prepared for the first time as a pure substance by photochemical selenation of P₄O₆ with red selenium. The compound crystallizes in a monoclinic system with space group P2₁/a (a = 973.6(2); b = 846.9(2); c = 1277.7(3) pm; β = 90.56(2)°; Z = 4; 1358 diffractometer data; R₁ = 0.044; wR² = 0.099). Bond lengths and angles within the molecule as well as the arrangement of the molecules within the crystal are discussed; vibrational (IR and Raman) and ³¹P-n.m.r. (solution) data are given.     

Cu3SbSe3: Synthese und Kristallstruktur

The Crystal Structure of Cu₃SbSe₃ The hitherto unknown crystal structure of Cu₃SbSe₃ has been determined from single crystals. The compound crystallizes in the orthorhombic system, space group Pnma (No. 62), with a = 7.9865(8), b = 10.6138(9) and c = 6.8372(7) Å, V = 579.6(1) ų, Z = 4. Most remarkable feature of the structure are groups of three cis-edge-sharing tetrahedra [Cu₃Se₈] which are interlinked to a threedimensional arrangement by SbSe₃-units. In contrast to Cu₃SbS₃ in the temperature range from ?180 to 25°C no hints for a phase transition could be detected by means of X-ray- and thermoanalytical methods.     

Synthese und Kristallstruktur von KTeOF3

Synthesis and Crystal Structure of KTeOF₃ KTeOF₃ has been synthesized by solid state reaction of KF, TeO₂ and KTeF₅ in equimolar amounts. Its crystal structure has been solved by single crystal structure analysis (P4₂/n, a = 1007.96(3), c = 789.58(3) pm, Z = 8, R₁ = 0.0311). As a characteristic feature, the compound contains unprecedented dimeric anions Te₂O₂F₆^2– formed by two edge‐sharing pseudo‐octahedral units. IR and Raman data are given.     

Kristallstruktur von gelbem K3OBr

Crystal Structure of Yellow K₃OBr K₃OBr was prepared for the first time and investigated by X-ray methods. The yellow compound crystallizes with cubic symmetry, space group Pm3m, a = 521.3(1) pm, Z = 1 and shows like colourless Na₃OCl anti-perovskite structure.     

Zur Synthese und Kristallstruktur von LiPdAlF6 und PdZrF6

Synthesis and Crystal Structure of LiPdAlF₆ and PdZrF₆ . For the first time single crystals of the new compounds LiPdAlF₆ and PdZrF₆ have been obtained. LiPdAlF₆ (blue) crystallizes trigonal, space group P3 1c—D (No. 163; LiCaAlF₆-type [2]), in an ordered structure variant of the Li₂[ZrF₆]-structure [3], with a=497.21(9) pm, c=914.0(9) pm and Z=2. PdZrF₆ (also blue) is isotypic with LiSbF₆ [4] and crystallizes trigonal-rhomboedric with a=552,3(1) pm, c=1 447,5(4) pm, space group R 3 —C (No. 148) and Z=3.