Chlorthionitrenkomplexe des Wolframs Die Kristallstruktur von [WCl4(NSCl)]2

Chlorothionitrene Complexes of Tungsten. Crystal Structure of [WCl₄(NSCl)]₂ Tungsten hexachloride reacts with trithiazyl chloride, (NSCl)₃, yielding the chlorothionitrene complex [WCl₄(NSCl)]₂, from which AsPh₄[WCl₅(NSCl)] can be obtained by reaction with AsPh₄Cl. Both complexes are characterized by their i.r. spectra. The crystal structure of [WCl₄(NSCl)]₂ was determined and refined with X-ray diffraction data (1059 reflexes, R = 0.055). It crystallizes in the monoclinic space group P2₁/n with the lattice constants a = 1523, b = 904, c = 583 pm and β = 91.35°. In the unit cell there are two centrosymmetric [WCl₄(NSCl)]₂ molecules in which the W atoms are linked via two chloro bridges; short and long W? Cl distances (244 and 265 pm) alternate in the W₂Cl₂ ring, the NSCl groups are found in the trans positions to the longer W? Cl bonds. The WNS bond angle (175°) and short bond distances correspond to a formulation .     

Chlorthionitrenkomplexe des Rheniums Die Kristallstruktur von AsPh4[ReCl4(NSCl)2] · CH2Cl2

Chlorothionitrene Complexes of Rhenium. Crystal Structure of AsPh₄[ReCl₄(NSCl)₂] · CH₂Cl₂ Rhenium pentachloride reacts in POCl₃ solution with (NSCl)₃ forming the chlorothionitrene complexes [(Cl₃PO)ReCl₄(NSCl)] ( I ) and [(Cl₃PO)ReCl₃(NSCl)₂] ( II ). I reacts with AsPh₄Cl in CH₂Cl₂ solution under abstraction of SCl₂ and POCl₃, yielding AsPh₄[ReNCl₄], while II forms the complex AsPh₄[ReCl₄(NSCl)₂] · CH₂Cl₂. The i.r. spectra of the compounds are discussed and assigned. The crystal structure of AsPh₄[ReCl₄(NSCl)₂] · CH₂Cl₂ was determined and refined with X-ray diffraction data (R = 0.031 for 2785 reflexions). It crystallizes in the space group Pī with two formula units per unit cell; the lattice constants are a = 1119, b = 1144, c = 1473 pm, α = 77.6, β = 70.8 and γ = 71.2°. The two NSCl ligands have cis arrangement with nearly linear Re?N?S groups, with interatomic distances corresponding to double bonds. The Re? Cl bonds are somewhat longer than usual and show no trans-effect; this is possibly due to Cl…?H? C bridges.     

N(SCl)2 ⊕[MoCl5(NSCl)]⊖, ein Chlorthionitrenokomplex von Molybdän(VI)

N(SCl)₂^⊕ [MoCl₅(NSCl)]^?, a Chlorothionitrene Complex of Molybdenum (VI) . The title compound is formed together with MoCl₃(N₃S₂) by the reaction of MoCl₄ or MoCl₅ with (NSCl)₃ in CH₂Cl₂. The black, crystalline compound was characterized by its i.r. spectrum and an X-ray crystal structure determination. N(SCl)₂^⊕[MoCl₅(NSCl)]^? crystallizes in the monoclinic space group P2₁/n with four formula units per unit cell. The lattice constants are a = 716.3, b = 1627.4, c = 1178.9 pm and β = 100.90°. The [MoCl₅(NSCl)]^? ion posseses an almost linear Mo = N = S grouping with bond lengths that can be interpreted as double bonds. Crystal data for AsPh₄[MoCl₅(NSCl)] are reported.     

Cyclo-S2N2-verbrückte Chlorthionitrenkomplexe von Molybdän und Wolfram. Die Kristallstruktur von μ-(S2N2)[MoCl4(NSCl)]2

Cyclo-S₂N₂ Bridged Chlorothionitrene Complexes of Molybdenum and Tungsten. Crystal Structure of μ-(S₂N₂)[MoCl₄(NSCl)]₂ Molybdenum pentachloride reacts with (NSCl)₃ in CH₂Cl₂ suspension giving a product mixture from which the complex μ-(S₂N₂)[MoCl₄(NSCl)]₂ can be extracted with CH₂Cl₂. It forms black crystals, whereas the corresponding tungsten compound forms copper-red crystals. μ-(S₂N₂)[WCl₄(NSCl)]₂ is obtained by abstraction of SCl₂ and chlorine from N(SCl)₂[WCl₅(NSCl)], which can be obtained from WCl₆ and N₂S₃Cl₂. According to their i.r. spectra both complexes μ-(S₂N₂)[MCl₄(NSCl)]₂ have the same molecular structure. The crystal structure of μ-(S₂N₂)[MoCl₄(NSCl)]₂ was determined and refined with X-ray diffraction data (1851 reflexions, R = 0.019). It crystallizes in the triclinic space group P1 with two molecules per unit cell. The lattice constants are a = 685, b = 735, c = 963 pm, α = 76.6°, β = 80.9°, γ = 87.0°. μ-(S₂N₂)[MoCl₄(NSCl)]₂ forms centrosymmetric molecules in which the Mo atoms of the MoCl₄(NSCl) units are linked via the N atoms of a planar N₂S₂ ring. The Mo atoms have coordination number 6, having the N atom of the chlorothionitrene ligand Mo in trans position to the N atom of the S₂N₂ ring.     

Nitrosyl-tetrachloro-dichlorphosphato-molybdat(+II); Darstellung,IR-Spektrum und Kristallstruktur von (AsPh4)2[Mo(NO)Cl4(O2PCl2)]

Nitrosyl-tetrachloro-dichlorophosphate-molybdate(+II); Preparation, I.R. Spectrum and Crystal Structure of (AsPh₄)₂[Mo(NO)Cl₄(O₂PCl₂)] The title compound is prepared by the reaction of AsPh₄[Mo(NO)Cl₄] with AsPh₄? [PO₂Cl₂] in dichloromethane solution. It forms orange crystals which are only little sensitive to moisture. The complex crystallizes triclinic in the space group P1 with two formula units in the unit cell. The structure was solved by X-ray diffraction methods (2498 observed, independent reflexions, R = 5.4%). The compound consists of AsPh₄^⊕ cations and [Mo(NO)Cl₄(PO₂Cl₂)]^2? anions. The NO ligand is coordinated in linear array \documentclass{article}\pagestyle{empty}\begin{document}$ \mathop {{\rm MO}}\limits^ \ominus = \mathop {\rm N}\limits^ \oplus = {\rm O}(177^{\circ}) $\end{document}. The dichlorophosphate group is coordinated in trans position to the NO ligand with one of its oxygen atoms. The Mo?N bonding of the NO ligand causes the bond angle NMoCl of 93.2° in average. The IR spectrum is recorded and assigned.     

Synthese,IR-Spektrum und Kristallstruktur von PPh4[OsCl4(NO)(NSCl)]

Synthesis, I.R. Spectrum, and Crystal Structure of PPh₄[OsCl₄(NO)(NSCl)] Molten trithiazyl chloride reacts with OsCl₃(NO) to yield a product mixture consisting mainly of S₄N₃[OsCl₄(NO)(NSCl)] and S₄N₃Cl. Extraction of this mixture with a solution of tetraphenylphosphonium chloride in dichloromethane affords green (PPh₄)₂[OsCl₅(NO)] · 2 CH₂Cl₂ and the red title compound. PPh₄[OsCl₄(NO)(NSCl)] was characterized by its IR spectrum and an X-ray crystal structure analysis (3001 independent observed reflexions, R = 0.048). Crystal data: monoclinic, space group P2₁/c, Z = 4, a = 1716, b = 1054, c = 1588 pm, β = 96.25°. The compound consists of PPh₄⊕ cations and [OsCl₄(NO)(NSCl)]? anions in which the nitrosyl and the chlorothionitrene ligands have a cis arrangement. Due to positional disorder the NO and NSCl groups are superimposed statistically in the structure model.     

Trägerfixierte Organometallkomplexe. VI. Charakterisierung und Reaktivität Polysiloxan-gebundener (Ether-phosphan)ruthenium(II)-Komplexe

Supported Organometallic Complexes. VI. Characterization und Reactivity of Polysiloxane-Bound (Ether-phosphane)ruthenium(II) Complexes The ligands PhP(R)CH₂D [R = (CH₃O)₃Si(CH₂)₃; D = CH₂OCH₃ ( 1b ); D = tetrahydrofuryl ( 1c ); D = 1,4-dioxanyl ( 1d )] have been used to synthesize (ether-phosphane)ruthenium(II) complexes, which have been copolymerized with Si(OEt)₄ to yield polysiloxane-bound complexes. The monomers cis,cis,trans-Cl₂Ru(CO)₂(P ～ O)₂ ( 3b ) and HRuCl(CO)(P ～ O)₃ ( 5b ) were treated with NaBH₄ to form cis,cis,trans-H₂Ru(CO)₂(P ～ O)₂ ( 4b ) and H₂Ru(CO)(P ～ O)₃ ( 6b ), respectively (P ～ O = η¹-P coordinated; = η²- coordinated). Addition of Si(OEt)₄ and water leads to a base catalyzed hydrolysis of the silicon alkoxy-functions and a precipitation of the immobilized counterparts 4b ′, 6b ′. The polysiloxane matrix resulting by this new sol gel route has been described under quantitative aspects by ²⁹Si CP-MAS NMR spectroscopy. 4b ′ reacts with carbon monoxide to form Ru(CO)₃(P ～ O)₂ ( 7b ′). Chelated polysiloxane-bound complexes Cl₂Ru( )₂ ( 9c ′, d ′) and Cl₂Ru( )(P ～ O)₂ ( 10b ′, c ′) have been synthesized by the reaction of 1b–c with Cl₂Ru(PPh₃)₃ ( 8 ) followed by a copolymerization with Si(OEt)₄. The polysiloxane-bound complexes 9c ′, d ′ and 10b ′, c ′ react with one equivalent of CO to give Cl₂Ru(CO)( )(P ～ O) ( 12b ′– d ′). Excess CO leads to the all-trans-complexes Cl₂Ru(CO)₂(P ～ O)₂ ( 14b ′– d ′), which are thermally isomerized to cis,cis,trans- 3b ′– d ′. The chemical shift anisotropy of ³¹P in crystalline Cl₂Ru( )₂ ( 9a , R = Ph, D = CH₂OCH₃) has been compared with polysiloxane-bound 9d ′ indicating a non-rigid behavior of the complexes in the matrix.     

Die Kristallstruktur von (AsPh4)2[W2NCl10]

Crystal Structure of (AsPh₄)₂[W₂NCl₁₀] The title compound is formed by a slow reaction of AsPh₄[WNCl₄] in acetonitrile solution in form of dark brown crystals. The crystal structure was solved by X-ray diffraction methods (R = 4.7%; 1461 observed, independent reflexions). (AsPh₄)₂[W₂NCl₁₀] crystallizes in the monoclinic space group P2₁/n with two formula units per unit cell. The structure consists of AsPh₄^θ and [W₂NCl₁₀]^2θ ions. The tungsten atoms with oxidation numbers five and six respectively, are linked by a linear, asymmetric nitrido bridge (r WN = 171 and 203 pm). The trans-effect of the W? N-multiple bonds causes a significant difference between axial (W? Cl_ax 243 pm) and equatorial (mean W? Cl_eq 230 pm) bond lengths.     

The determination of the arrhenius parameters for the reaction Cl + C2F5I → ICl + C2F5 using a competitive method

The reactions have been studied competitively over the range of 28–182°C by photolysis of mixtures of Cl₂ + C₂F₅I+ CH₄. We obtain where θ = 2.303RT J/mol. The use of published data on reaction (2) leads to log (k₁cm³/mol sec) = (13.96 ± 0.2) ? (11,500 ± 2000)/θ.     

Zur Natur von Trinatriumorthonitrat

Syntheses and I.R. Spectra of [Br₄Re?N? BBr₃]^? and [ReNBr₄]^?. Crystal Structure of AsPh₄[ReNBr₄] AsPh₄[Br₄Re?N? BBr₃] is obtained from AsPh₄[ReNCl₄] and excess boron tribromide, forming dark violet crystals, sensitive to moisture. Thermal cleavage at 210°C in vacuo yields red-orange AsPh₄[ReNBr₄]. According to the i.r. spectra the complex anions of both compounds contain ReN triple bonds; in [Br₄Re?N? BBr₃]^? the sp-hybridised nitrogen is part of a linear bridge . The crystal structure of AsPh₄[ReNBr₄] was determined by aid of X-ray diffraction data (1 168 unique reflexions, R = 3.8%). The compound crystallises in the tetragonal space group P 4/n with two formula units per unit cell and the cell dimensions a = b = 1 290 pm and c = 795.4 pm. The anion [ReNBr₄]^? has C_4v symmetry with a bond angle NReBr of 103° and the ReN bond length (162 pm) corresponding to a triple bond.     

Thiohalogeno-Verbindungen von Niob und Tantal: NbSCl3, TaSCl3, [NbSCl5]2−, [TaSCl5]2−, [NbSBr4]− Die Kristallstrukturen von (PPh4)2[NbSCl5] · 2 CH2Cl2 und NEt4[NbCl6]

Thiohalo Compounds of Niobium and Tantalum: NbSCl₃, TaSCl₃, [NbSCl₅]^2?, [TaSCl₅]^2?, [NbSBr₄]^?. Crystal Structures of (PPh₄)₂[NbSCl₅] · 2 CH₂Cl₂ and NEt₄[NbCl₆] NbSCl₃ can be obtained from NbCl₅ by reaction with H₂S or bistrimethylsilyl sulfide in a suspension of CCl₄ or CH₂Cl₂, respectively; in the latter case the product contains a rest of trimethylsilyl groups. This also applies for TaSCl₃, NbSBr₃ and TaSBr₃, which are formed from the metal pentahalides and S(SiMe₃)₂. NEt₄[NbSCl₄] is formed together with NEt₄[NbCl₆] in the reaction of NbCl₅ with NEt₄SH in CH₂Cl₂. PPh₄[NbCl₆] reacts with S(SiMe₃)₂ in dichloromethane yielding (PPh₄)₂[NbSCl₅] · 2 CH₂Cl₂, whereas PPh₄[NbSBr₄] is obtained from PPh₄[NbBr₆] and S(SiMe₃) under the same conditions. (PPh₄)₂[TaSCl₅] · 2 CH₂Cl₂ was obtained from TaSCl₃ and PPh₄Cl in CH₂Cl₂. According to an X-ray crystal structure determination (PPh₄)₂[NbSCl₅] · 2 CH₂Cl₂ crystallizes in the β-(AsPh₄)₂[UCl₆] · 2 CH₂Cl₂ type with positionally disordered, octahedral anions. Crystal data: a = 1 021.7, b = 1120.4, c = 1 243.3 pm, α = 70.77, β = 80.24, γ = 80.54°, space group P1 , Z = 2; 2462 unique observed reflexions, R = 0.036. NEt₄[NbCl₆] crystallizes isotypic to NEt₄[WCl₆], a = 723.5, b = 1 018.0, c = 1 174.6 pm, β = 100.07°, space group P2₁/n, Z = 2; 1 875 reflexions, R = 0.075.     

Thionitrosylkomplexe des Osmiums. Die Kristallstruktur von AsPh4[OsCl4(NS)2Cl]

Thionitrosyl Complexes of Osmium. Crystal Structure of AsPh₄[OsCl₄(NS)₂Cl] The reaction of osmium pentachloride with trithiazyl chloride (NSCl)₃ yields the thiazylchloride complex [OsCl₄(NSCl)₂], from which the thionitrosyl complex AsPh₄[OsCl₄(NS)₂Cl] is obtained by reaction with AsPh₄Cl in CH₂Cl₂. From this, the neutral thionitrosyl complex [OsCl₄(NS)₂] forms by chloride abstraction with gallium trichloride. The crystal structure of AsPh₄[OsCl₄(NS)₂Cl] was determined and refined with the aid of X-ray diffraction data (R = 0.033, 2161 reflexions). It crystallizes in the monoclinic space group P2₁/c with four formula units per unit cell. The lattice constants are a = 1735, b = 1058, c = 1578 pm and β 95.64°. In the [OsCl₄(NS)₂Cl]^? ion the osmium is octahedrally coordinated by four Cl atoms and two NS groups in a cis arrangement. The NS groups are essentially linear with the bond lengths Os?N 184 pm and N?S 146 pm. Loosely attached to one of the S atoms there is a Cl atom (S? Cl distance 228 pm); in the crystal it statistically belongs to both S atoms with an occupation probability of one half, and it cannot be decided whether there is a dynamical fluctuation between the S atoms or a static positional disorder. However, according to the i.r. spectrum the dynamical model seems more probable.     

4-Methyl-1,2,3,5-dithiadiazoliumsalze Die Kristallstrukturen von (CH3CN2S2)5[CoCl4]Cl3 und (CH3CN2S2)Cl

4-Methyl-1,2,3,5-dithiadiazolium Salts. Crystal Structures of(CH₃CN₂S₂)₅[CoCl₄]Cl₃ and (CH₃CN₂S₂)Cl 4-Methyl-1,2,3,5-dithiadiazolium tetrachlorocobaltate trichloride, (CH₃CN₂S₂)₅[CoCl₄]Cl₃, was obtained by reaction of trithiazyl chloride, (NSCl)₃, with CoCl₂ in acetonitrile; it forms brown, moisture sensitive crystals. With tetraphenylarsonium chloride in CH₂Cl₂ it yields yellow crystalline (CH₃CN₂S₂)Cl and (AsPh₄)₂CoCl₄. The IR spectra of the title compounds are reported and assigned. Theit crystal structures were determined by X-ray diffraction. Crystal data: (CH₃CN₂S₂)₅[CoCl₄]Cl₃, orthorhombic, P2₁2₁2₁, Z = 4, a = 830, b = 1603, c = 2443 pm at 180 K (structure determination with 1787 observed independent reflexions, R = 0.070); (CH₃CN₂S₂)Cl, triclinic, P2₁2₁2₁, Z = 4, a = 749, b = 819, c = 1015 pm, α = 84.9, β = 67.4, γ = 84.6° at 296 K (2653 reflexions, R = 0.040). Both compounds are ionic, having chloride and distorted tetrahedral CoCl₄^2? anions and planar 4-methyl-1,2,3,5-dithiadiazolium cations which nearly fulfill C_2v symmetry. The (CH₃CN₂S₂)₅[CoCl₄]Cl₃ structure contains five symmetry independent cations, (CH₃CN₂Cl has two symmetry independent cations, all being nearly equal. No nitrogen atom but all sulfur atoms of the cations have contact with three to five chlorine atoms, and as a rule there is one chloride ion which is coplanar with the cation and exhibits rather short distances to both S atoms (288 to 309 pm); therefore, the positive charge of the cations must be concentrated on the sulfur atoms.     

Kristallstrukturen,Schwingungsspektren und Normalkoordinatenanalysen der stereoisomeren Trifluorotrichloroplatinate(IV), fac-[(C5H5N)2CH2][PtF3Cl3] · 0,5(CH3)2CO und mer-[(C5H5N)2CH2][PtF3Cl3]

Crystal Structures, Vibrational Spectra, and Normal Coordinate Analyses of the Stereoisomeric Trifluorotrichloroplatinates(IV), fac-[(C₅H₅N)₂CH₂][PtF₃Cl₃] · 0.5(CH₃)₂CO and mer-[(C₅H₅N)₂CH₂][PtF₃Cl₃] The geometric isomers fac- und mer-[PtF₃Cl₃]^2? have been isolated by ion exchange chromatography on diethylaminoethyl cellulose. The doubly charged complex anions form stable AB-type salts with the dication dipyridiniomethane, [(C₅H₅N)₂CH₂]²⁺. The X-ray structure determination on single crystals of fac-[(C₅H₅N)₂CH₂][PtF₃Cl₃] · 0,5(CH₃)₂CO ( 1 ) (triclinic, space group P1 with a = 8.468(3), b = 8.847(2), c = 12.1260(10) Å, α = 79.986(12), β = 79.009(12), γ = 69.20(3)°, Z = 2) and mer-[(C₅H₅N)₂CH₂][PtF₃Cl₃] ( 2 ) (monoclinic, space group P2₁/n with a = 9.620(2), b = 14.031(4), c = 10.435(3) Å, β = 97.54(2)°, Z = 4) reveals the perfect ordering of the anion sublattice. Due to the stronger trans influence of Cl compared to F in asymmetric axes $ {\rm F}^. $? Pt? Cl′ the Pt? $ {\rm F}^. $ distance is lengthened by 1.8%, the Pt? Cl′ distance is shortened by 1.2% in comparison with symmetrically coordinated axes. Correspondingly, the vibrational spectra exhibit shifts of the Pt$ {\rm F}^. $ streching vibrations by 8% to lower, and of the PtCl′ streching vibrations by 12% to higher frequencies. Normal coordinate analyses performed on the basis of the X-ray data result in valence force constants for weakened Pt? $ {\rm F}^. $ bonds to be 14% lower, for the strengthened Pt? Cl′ bonds to be 20% higher than in symmetric axes, respectively. Generally the trans influence in fluorochloroplatinates(IV) on the bond lengths is very low with 1–2%, it results in considerable shifts of the stretching vibrations by 8–12% and reveals the strongest effect on the valence force constants with 14–20%.     

Synthese und NMR-Spektren von λ5-Diphospheten Die Struktur des 2,4-Diphenyl-1,1,3,3-tetrakis(diethylamino)-1λ5,3λ5-diphosphets

Synthesis and NMR Spectra of λ⁵-Diphosphets. Structure of 2,4-Diphenyl-1,1,3,3-tetrakis (diethylamino)-1λ⁵, 3λ⁵-diphosphete Preparation, properties, and n.m.r. spectra of C₂H₅PF₂[N(C₂H₅)₂]₂, CH₂?PF[N(C₂H₅)₂]₂, and the diphosphetes {RC?P[N(C₂H₅)₂]₂}₂ (R) ? H ( 5a ), CH₃ [( 5b )] are described. The λ⁵-diphosphete {HC?P(NR₂)₂}₂ (R ? CH₃) reacts with BF₃ · O(C₂H₅)₂ to give which is transformed into by n-C₄H₉Li. The crystal and molecular structure of 2,4-diphenyl-1,3,3-tetrakis(diethylamino)-1λ⁵,3λ⁵-diphosphete 2 are reported and discussed.     

(AsPh4)2[(μ-N2S2) (VCI5)2] Synthese,IR-Spektrum und Kristallstruktur

(AsPh₄)₂[(μ-N₂S₂)(VCl₅)₂]. Synthesis, I.R. Spectrum, and Crystal Structure From the reaction of VCl₄ and S₃N₂Cl₂ in CCl₄ solution a solid, black product mixture is obtained. From this, the title compound can be extracted by reaction with AsPh₄Cl in CH₂Cl₂ solution. It can also be synthesized from AsPh₄VCl₅ and S₃N₃Cl₃ in CH₂Cl₂ solution. The i.r. spectra of (AsPh₄)₂[(μ-N₂S₂)(VCl₅)₂] (black crystal plates) and AsPh₄VCl₅ (brown needles) are reported. The crystal structure of (AsPh₄)₂[(μ-N₂S₂)(VCl₅)₂] was determined by X-ray diffraction. It crystallizes in the monoclinic space group P2₁/c with two formula units per unit cell. The lattice constants are a = 1113.9, b = 1712.8, c = 1508.8 pm, β = 106.68°. The centrosymmetric [(μ-N₂S₂)(VCl₅)₂]^2? ion consists of two quadratic-pyramidal VCl₅ units which are linked via the N atoms of a N₂S₂ ring. The N₂S₂ ring shows positional disorder in two different orientations in the crystal. The AsPh₄⊕ ions form (AsPh₄⊕)₂ pairs via inversion centers, each pair is surrounded by eight anions.     

Nitrosylkomplexe des Molybdän(+II) Die Kristallstrukturen von [Mo(NO)Cl3 · POCl3]2 und von [AsPh4]2[Mo(NO)Cl5] · 2 CH2Cl2

Nitrosyl Complexes of Molybdenum (+II). Crystal Structures of [Mo(NO)Cl₃ · POCl₃]₂ and [AsPh₄]₂[Mo(NO)Cl₅] · 2 CH₂Cl₂ Solutions of MoCl₅ in POCl₃ react with NOCl forming the nitrosyl compound Mo(NO)Cl₃ · 2POCl₃ ( I ), which in CH₂Cl₂ cleaves off one solvate molecule, yielding the dimeric complex [Mo(NO)Cl₃ · POCl₃]₂ ( II ). Reaction with AsPh₄Cl in dichloro methane leads to the nitrosyl complexes AsPh₄[Mo(NO)Cl₄] · CH₂Cl₂ ( III ) and [AsPh₄]₂[Mo(NO)Cl₅] · 2CH₂Cl₂ ( IV ), respectively. The i.r. spectra are recorded and assigned. [Mo(NO)Cl₃ · POCl₃]₂ crystallizes monoclinic in the space group P2₁/c with two dimeric units per unit cell. The crystal structure was determined by X-ray diffraction methods (R = 0.040; 1391 observed, independent reflexions). Complex II is linked by chlorine bridges, forming a dimeric, centrosymmetric molecule of symmetry C_i. The N? O bond of the nitrosyl ligand is extremely short (108 pm), the Mo? N bond (181 pm) corresponds to a double bond. In trans position to the NO ligand, which is coordinated in linear array, there is the O atom of the solvate molecule POCl₃. [AsPh₄]₂[Mo(NO)Cl₅] · 2 CH₂Cl₂ crystallizes triclinic in the space group P1 with two units per unit cell (R = 0.039; 1967 observed, independent reflexions). The molybdenum atom is coordinated octahedrally by five Cl ligands and a nitrosyl group, as well coordinated in linear array (Mo? N? O 174°). The nitrosyl ligand exerts a significant trans-effect (r Mo? Cl_(trans) = 247 pm, r MoCl_4(eq)(average) = 239 pm).     

Chlorthionitrenkomplexe des Molybdäns

Chlorothionitrene Complexes of Molybdenum Molybdenum pentachloride reacts with trimer thiazylchloride, (NSCl)₃, forming the chlorothionitrene complex \documentclass{article}\pagestyle{empty}\begin{document}$ {\rm Cl}_4 {\rm Mo} = \mathop {\rm N}\limits^ \oplus = \mathop {{\rm SCl}}\limits^ \ominus $\end{document}, in which the chlorothionitrene ligand is to be understood as (NSCl)^2? group. I reacts with phosphorylchloride forming the solvate Cl₃PO? Mo(Cl₄)(NSCl) ( II ) that can also be obtained directly from MoCl₅ · OPCl₃ and trithiazylchloride. II reacts with chloride ions giving the anionic chlorothionitrene complex [Cl₅Mo(NSCl)]? ( III ). Thermal decomposition of I leads to MoNCl₃ under SCl₂ cleavage, while reaction of I with chloride ions gives [MoNCl₄]?. Both reactions prove chlorothionitrene complexes to be excellent precursors for the syntheses of nitrido complexes. The complexes I—III have been characterized by IR spectroscopy.     

Synthese und Struktur neuer Tetrafluoroaurate(III), TlF2[AuF4], M2F[AuF4]5 (M = Bi,La, Y) und Sm[AuF4]3

Synthesis and Structure of Tetrafluoroaurates(III), TlF₂[AuF₄], M₂F[AuF₄]₅ (M = Y, La, Bi), Sm[AuF₄]₃ with an Appendix on Sm[AuF₄]₂ In the system MF₃/AuF₃ the structures of several yellow Tetrafluoroaurates(III) have been determinated. TlF₂[AuF₄] crystallizes tetragonal, space group P4₁2₁2 – D (Nr. 92) with a = 573.17(4) pm, c = 2780.4(3) pm, Z = 8; M₂F[AuF₄]₅ (M = Bi, La) tetragonal, space group P4₁2₁2 – D (Nr. 92) with a = 822.89(5) pm, c = 2557.1(3) pm, Z = 4 (Bi); with a = 836.80(3) pm, c = 2602.2(2) pm, Z = 4 (La); Y₂F[AuF₄]₅ monoclin, space group P2/n – C (Nr. 13) with a = 1188.9(3) pm, b = 797.4(2) pm, c = 895.7(3) pm, β = 89.18(3), Z = 4 and Sm[AuF₄]₃ trigonal, space group R3c – D (Nr. 167) with a = 1034.5(1) pm, c = 1614.1(3) pm, Z = 6. All these yellow crystals have been obtained by solid state reactions in autoclaves or sealed goldtubes.     

S5N5⊕[GaCl4]⊖ und S5N5⊕[Ga2Cl7]⊖. Synthesen,IR-Spektren und Kristallstrukturen

S₅N₅ ^⊕[GaCl₄]^? and S₅N₅ ^⊕[Ga₂Cl₇]^?. Synthesis, IR Spectra, and Crystal Structures . S₅N₅[GaCl₄] was obtained in high yields from gallium and trithiazyl chloride; depending on the solvent, different second products are formed: S₄N₄Cl[GaCl₄] in dichloromethane and S₃N₂Cl[GaCl₄] in carbon tetrachloride. These products can be separated due to their high solubility in CH₂Cl₂, S₅N₅[GaCl₄] being only slightly soluble. S₃N₂Cl[GaCl₄] can be converted to S₅N₅[GaCl₄] with additional (NSCl)₃. By the action of GaCl₃ on S₅N₅[GaCl₄], S₅N₅[Ga₂Cl₇] is formed. The IR spectra of the title compounds are reported; they differ considerably as well in number as in frequencies of the cation bands and show that the S₅N₅^⊕ ion has different structures depending on the anion. The crystal structures of both compounds were determined by X-ray diffraction. Crystal data: S₅N₅[GaCl₄], orthorhombic, a = 943.8, b = 1369.0, c = 2068.8 pm, space group Pnma, Z = 8 (1381 observed reflexions, R = 0.075); S₅N₅[Ga₂Cl₇], monoclinic, a = 847.5, b = 1298.2, c = 1654.0 pm, β = 93.51°, space group P2₁/n, Z = 4 (1359 observed reflexions, R = 0.065). S₅N₅[GaCl₄] is isotypic with S₅N₅[AlCl₄], showing a heartshaped S₅N₅^⊕ ion, but large ellipsoids of vibration suggest the presence of some kind of disorder (statical or dynamical). In S₅N₅[Ga₂Cl₇] the S₅N₅^⊕ has an azulene-like structure. In both cases the cations are planar, all S? N bond lengths being approximately equal.