Hochdrucksynthese und Struktur von Rb2PtH6 und Cs2PtH6, ternären Hydriden mit K2PtCl6-Struktur

High-pressure Synthesis and Structure of Rb₂PtH₆ and Cs₂PtH₆, Ternary Hydrides with K₂PtCl₆-Structure The ternary platinum hydrides Rb₂PtH₆ and Cs₂PtH₆ were synthesized by the reaction of rubidium hydride and cesium hydride, respectively, with platinum sponge under a hydrogen pressure above 1 500 bar at 500°C. X-ray investigations on powdered samples and elastic neutron diffraction experiments on the deuterated compounds at the time-of-flight spectrometer POLARIS led to their complete structure determination. Their atomic arrangements are isotypic with that of K₂PtCl₆ containing isolated [PtH₆]^2?-octahedra (space group: Fm3 m, Z = 4).     

Calcium–Rhodium–Hydride –- Synthese und Struktur

Calcium Rhodium Hydrides –- Synthesis and Structure The two ternary hydrides Ca₈Rh₅H₂₃ and Ca₈Rh₆H₂₄ can be synthesised by reacting calcium hydride with rhodium in a hydrogen atmosphere. X-ray investigations on powder samples and elastic neutron diffraction experiments on the deuterated compounds led to the complete structures. Both hydrides crystallise in cubic structure types representing a transition from the K₂PtCl₆ type to the perovskit type structure. The rhodium deuterium bond lengths and the atomic volume of deuterium were discussed.     

Synthese und Struktur von Li3RhH6, einem ternären Hydrid mit isolierten [RhH6]3−-Oktaedern

Synthesis and Structure of Li₃RhH₆ — a Ternary Hydride with Isolated [RhH₆]^3? Octahedra The ternary rhodium hydride Li₃RhH₆ was synthesized by the reaction of lithium hydride with rhodium under a hydrogen pressure of 80 bar. X-ray investigations on powdered samples and an elastic neutron diffraction experiment on the deuterated compound led to the complete structure determination (space group: Pnma, Z = 4). The atomic arrangement is isotypic to the Na₃RhH₆ structure type. The crystal structure contains isolated [RhH₆]^3? octahedra, which are separated by the lithium ions.     

K3ReH6 – Synthese,Struktur und magnetische Eigenschaften

K₃ReH₆ – Synthesis, Structure, and Magnetic Properties K₃ReH₆ and K₃ReD₆ were synthesized by the reaction of potassium hydride (deuteride) with rhenium powder under a hydrogen pressure between 3000–3500 bar at 850 K. X-ray investigations on powdered samples and elastic neutron diffraction experiments on the deuterated compound at the triple axis spectrometer TAS 1 in the temperature range 5–600 K led to the atomic arrangement, which corresponds to that of the cryolite with [ReH₆]^3–-octahedra as characteristic units. Magnetic susceptibility measurements in the temperature range from 3.5 K and room temperature revealed a weak temperature independent paramagnetism. Quantum mechanical calculations confirm these facts and show in detail that the large value of the spin-orbit coupling parameter is essential for the magnetic behaviour.     

Na3RuD7 – Synthese und Struktur

Na₃RuD₇ – Synthesis and Structure Na₃RuD₇ was synthesized by the reaction of sodium deuteride with ruthenium powder under a hydrogen pressure of 6000 bar at 900 K. X‐ray investigations on powdered samples and elastic neutron diffraction experiments led to the atomic arrangement (space group: P4₂/mnm), which is characterized by isolated [RuD₇]‐anions. The coordination polyhedron formed by the seven deuterium ligands can be described as a distorted pentagonal bipyramide.     

K3MnH5, das erste salzartige Manganhydrid

K₃MnH₅, the First Salt-like Manganese Hydride K₃MnH₅ and K₃MnD₅ were synthesized by the reaction of potassium hydride (deuteride) with manganese powder under a hydrogen pressure above 3000 bar at 875 K. X-ray investigations on powdered samples and elastic neutron diffraction experiments on the deuterated compound at the time-of-flight spectrometer LAD in the temperature range 5–600 K led to the complete structure determination. The atomic arrangement is isotypic with that of Cs₃[CoCl₄]Cl (space group: 14/mcm, Z = 4). The structure of K₃MnH₅ contains isolated [MnH₄]^2?-tetrahedra and additional hydrogen ions which are exclusively coordinated by potassium cations. The magnetic susceptibilities show Curie-Weiss behaviour. At temperatures below 50 K there are obviously antiferromagnetic interactions.     

Na3OsH7 – Synthese,Struktur und magnetische Eigenschaften,sowie Untersuchungen zur Existenz einer analogen Rutheniumverbindung

Na₃OsH₇ – Synthesis, Structure, and Magnetic Properties as well as Investigations on the Existence of the Analogous Ruthenium Compound Na₃OsH₇ was synthesized by the reaction of sodium hydride with osmium powder under a hydrogen pressure of more than 1500 bar at 870 K. X‐ray investigations on powdered samples and elastic neutron diffraction experiments on the deuterated compound led to the atomic arrangement (space group: P4₂/mnm), which is characterized by isolated [OsD₇]‐anions. The coordination polyhedron formed by the seven deuterium ligands can be described as a distorted pentagonal bipyramide. Magnetic susceptibility measurements in the temperature range between 3.5 K and room temperature revealed a weak temperature independent paramagnetism. Quantum mechanical calculations confirm these facts and show in detail that the large value of the spin‐orbit coupling constant is responsible for the magnetic behaviour of the osmium (IV) compound. To synthesize the analogous ruthenium hydride it was necessary to increase the hydrogen pressure during the reaction up to 5000 bar. X‐ray investigations showed that Na₃RuH₇ crystallizes in an atomic arrangement isotypic to that of the osmium compound.     

Ca2RhD5.4 – Strukturbestimmung über Neutronenbeugungsexperimente

Ca₂RhH_5.4 – Structure Determination via Neutron Diffraction Experiments The structure of Ca₂RhH₅ described by Moyer et al. is only known respective to the arrangement of the metal atoms. Elastic neutron diffraction experiments on the deuterated compound led to the complete structure, which corresponds to that of the K₂PtCl₆ type structure with the chloride sites statistically occupied in accordance with the formula of the mixed valent compound Ca₂RhD_5.4. A neutron diffraction diagram of a high resolution T–O–F spectrometer led to the up to now unknown compound Ca₈Rh₅D₂₃ which crystallises isotypic to the analogous strontium compound in an atomic arrangement representing a transition from the K₂PtCl₆ type to the perovskite type structure.     

Darstellung und Struktur der Tetrafluoroaurate(III) MI[AuF4] mit MI = Li,Rb

Synthesis and Structure of Tetrafluoroaurates(III) M^I[AuF₄] with M^I = Li, Rb Single crystal investigations on Rb[AuF₄], light yellow, confirm the tetragonal unit cell (K[BrF₄]-type) with a = 618.2(1) and c = 1191(1) pm, Z = 4, space group I 4/mcm-D (No. 140). Li[AuF₄], light yellow too, crystallizes monoclinic with a = 485.32(7), b = 634.29(8), c = 1004.43(13) pm, β = 92.759(12), Z = 4; space group P 2/c-C (No. 13). The structure of Li[AuF₄] is related to the Rb[AuF₄]-type of structure.     

CsC2H: Synthese,Kristallstruktur und spektroskopische Eigenschaften

CsC₂H: Synthesis, Crystal Structure, and Spectroscopic Properties CsC₂H was synthesised by the reaction of caesium solved in liquid ammonia with acetylene. The crystal structure could be solved and refined from X‐ray and neutron powder diffraction data (space group: R3c, Z = 18). The structure is characterised by C₂H^– trimers which are surrounded by caesium ions. Spectroscopic investigations (IR and Raman) of the stable monoalkalimetal acetylides mainly confirm the data given in the literature and show that the alkalimetal cation has a marked influence on the vibrational properties of the C₂H^– anion.     

Darstellung und Struktur von Li5Ga4

Preparation and Crystal Structure of Li₅Ga₄ Li₅Ga₄ has been established as further, hitherto unknown phase in the LiGa system. The new compound crystallizes in the trigonal system (P3 m1—D_3d³) with a = 437.5 ± 0.2 pm, c = 825.7 ± 0.2 pm, c/a = 1.885. The structure is strongly related to those of LiGa and Li₃Ga₂.     

Darstellung und Kristallstruktur von [Li(DME)2I]

Synthesis and Crystal Structure of [Li(DME)₂I] . LiI can be dissolved at 50°C in toluene/DME (2:1). At - 20°C [Li(DME)₂I] ( 1 ) was isolated in 75% yield. 1 was characterized by NMR techniques as well as an X-Ray structure determination. 1 crystallizes in the space group C2/c with a = 1 356.9(2), b = 813.2(1), c = 1 259.1(2) pm, and β = 99.74(1)°.     

Darstellung und Struktur eines Ammoniumdiamidodioxophosphats(V), NH4PO2(NH2)2

Synthesis and Structure of an Ammonium Diamidodioxophosphate(V), NH₄PO₂(NH₂)₂ The ammonolysis of P₃N₅ under ammonothermal conditions (T = 400°C, p(NH₃) = 6 kbar, 14 d in autoclaves) in the presence of small definite amounts of water leads to the formation of NH₄PO₂(NH₂)₂. The structure was solved by single crystal X-ray methods. NH₄PO₂(NH₂)₂: P2₁/c (Nr. 14), a = 6.886(1) Å, b = 8.366(2) Å, c = 9.151(2) Å, β = 111.78(3)°, Z = 4, R₁/wR₂ = 0.026/0.072, Z(F > 2σ(F)) = 1183, N(variables) = 87. In NH₄PO₂(NH₂)₂ the anions [PO₂(NH₂)₂]^? are linked to chains by N? H …? N and N? H …? O bridge bonds. The ammonium ions are located between these chains and are donors for N? H …? O bridge bonds which connect the chains three-dimensionally.     

铂氢化物trans-[PtH(tu)(PPh_3)_2]Cl(tu)(THF)_2(tu=SC(NH_2)_2)的结构

制得含硫脲配体的铂氢化物单晶trans-[PtH(tu)(PPh_3)_2]Cl(tu)(THF)_2,其结构测定结果为:C_(46)H_(55)N_4O_2P_2S_2ClPt M=1052.6,单斜晶系,空间群为 P2_1/c,a=12.103(1),b=21.619(3),c=20.189(4)(?),β=103.31(0)°,V=5140(2)(?)~3,Z=4,D_c=1.360g·cm~(-3),F(000)=2128,R=0.050,R_w=0.063.Pt(Ⅱ)与两个磷、一个硫脲分子的硫和一个氢相配合,形成四边形配位。     

Zur Reaktion der Lanthanoiden mit Chelatliganden Darstellung und Struktur von [(py2CH)3Gd]

On the Reaction of the Lanthanides with Chelate Ligands Synthesis and Crystal Structure of [(py₂CH)₃Gd] GdBr₃ reacts with [(py₂CH)Li] to the mononuclear complex [(py₂CH)₃Gd] 1 . The structure of 1 was characterized by X-ray single crystal structure analysis. Space group P2₁, Z = 2, a = 951.4(10) pm, b = 1369.4(10) pm, c = 1074.5(10) pm, β = 105.69(8)°. The Gd-Ion is surrounded by the six nitrogen atoms of the three chelate ligands and shows a distorted trigonal prismatic coordination. As a difference to the lithium salt of the ligand, the six-membered metalla-cycles in 1 are not planar, but show a boat conformation.     

Darstellung und Struktur von Tetraethylcyclotetraarsoxan-Komplexen von Kupfer(I)-Halogeniden

Preparation and Structure of Tetraethylcyclotetraarsoxane Complexes of Copper(I) Halides The polymeric complexes [Cu₄Cl₄{cyclo-(C₂H₅AsO)₄}₃]_n ( 1 ), [Cu₃Br₃{cyclo-(C₂H₅AsO)₄}₂]_n ( 2 ) and [Cu₆I₆{cyclo-(C₂H₅AsO)₄}₃]_n ( 3 ) were prepared by the reaction of (C₂H₅AsO)_n and CuX (X = Cl, Br, I) in acetonitrile and characterised by X-ray analysis. All three complexes contain only tetramers (C₂H₅AsO)₄ as ligands, in which the As₄O₄ ring systems coordinate between two and four Cu-atoms. In each case one As₄O₄ ring with a crown-shaped conformation is observed, which coordinates either four (in 1 ) or three (in 2 and 3 ) axially sited Cu-atoms. In addition there are further (C₂H₅AsO)₄ ligands, which display either a boat-chair- (in 1 ) or a twist-chair-conformation (in 1–3 ). The individual building units are connected to one another via Cu? X? Cu bridges (in 2 and 3 ) and/or centrosymmetric As₄O₄ ring systems (in 1–3 ) into chain ( 1 ) or layer structures ( 2 und 3 ).     

Darstellung,Struktur und magnetische Eigenschaften der Natriumeisenchalkogenide Na6FeS4 und Na6FeSe4

Synthesis, Structure, and Magnetic Properties of the Sodium Iron Chalcogenides Na₆FeS₄ and Na₆FeSe₄ The compounds Na₆FeS₄ and Na₆FeSe₄ have been synthesized by fusion reactions of sodium carbonate with iron and chalcogen in a stream of hydrogen. Structural investigations on single crystals show that both compounds crystallize in an atomic arrangement isotypic with Na₆ZnO₄ (space group P6₃mc). The structure is characterized by isolated [FeX₄]-tetrahedra. The magnetic susceptibilities show Curie-Weiss behaviour. The deviations at low temperatures are obviously caused by antiferromagnetic interactions.     

Darstellung,Kristallstruktur und Eigenschaften von KLi2As

Preparation, Crystal Structure, and Properties of KLi₂As The novel arsenide KLi₂As has been synthesized either from the elements or from mixtures of the binary components Li₃As and K₃As in sealed Nb ampoules at 823 K and 623 K, respectively. It crystallizes in the space group Pmmn (no. 59) with a = 445.8(9); b = 671.5(11); c = 627.0(12) pm and Z = 2 formula units. The metallic reflecting silvercoloured platelets hydrolize rapidly under wet air. The compound (Pearson code oP8) is isopuntal with BaLi₂Si and an intermediate between the Li₃N and the Na₃As type of structure. Potassium is distorted tetrahedrally coordinated by four As atoms (d(K? As) = 355 and 367 pm), arsenic by four potassium and six lithium atoms (d(As? K) = 355–367 pm; d(As? Li) = 260–265 pm) in form of a sphenocorona. Lithium is threefold coordinated (distorted trigonal planar) by arsenic and this unit is enveloped by a monocapped trigonal prism build by three lithium and four potassium atoms.