Darstellung und Eigenschaften von Trifluormethylmercaptothiophosphoryldichlorid

Preparation and Properties of Trifluoromethylmercaptothiophosphoryldichloride The reaction of CF₃SP(O)Cl₂ with SPCl₃ leads to a CF₃S-chlorine exchange and gives CF₃SP(S)Cl₂ in 50% yield. A controlled hydrolysis of CF₃SP(O)Cl₂ affords CF₃SP(O)(OH)₂, that cannot be isolated as such, but it condenses to CF₃SP(O)(OH)O? [P(SCF₃)(O)? O]_nP(O)(OH)SCF₃. On the other hand, CF₃SP(S)Cl₂ reacts with water to yield H₃PO₄, CF₃SH, S₈, and HCl. CF₃SP(X)Cl₂ reacts with alcohols to give CF₃SP(X)(OR)₂ [R = CH₃, C₂H₅, n-C₃H₇, CH(CH₃)₂, n-C₄H₉ and for X = O, R = C₆H₅, too]. The formation of semi-esters CF₃SP(X)Cl(OR′) could be proven for X = O, R′ = CH₃, C₆H₅ and for X = S, R′ = R. While CF₃SP(O)(OC₂H₅)₂ rapidly decomposes into SCF₂ and FP(O)(OC₂H₅)₂, the other compounds and primarily CF₃SP(O)(OCH₃)₂ and CF₃SP(S)(OR)₂ ar stable. The reaction between CF₃SCl and CH₃SPCl₂ results in CF₃SCH₂SPCl₂ and that between CF₃SP(O)Cl₂ and AlCl₃ gives [CF₃SP(O)Cl]⁺[AlCl₄]^?. Physical and spectroscopical data are given for the newly formed compounds.     

14/15N-NMR und 11B-NMR-Daten von Trifluormethylthioaminoboranen mit natürlicher Isotopenhäufigkeit

^14/15N N.M.R. and ¹¹B N.M.R. Data of Trifluoromethylthioamino-boranes with Natural Isotope Abundance (Part 2) ^14/15N as well as ¹¹B-NMR data for trifluoromethylthioabminoboranes of the types XnB[N(SCF₃)₂], with X = F, Cl, Br, N₃, or NHSCF₃, n = 0, 1 or 2, and Cl_3?nB(NHSCF₃)n with n = 1, 2 or 3, as well as for the amine-borne Me₃NBCl₂N(SCF₃)₂ and the cyclic borazene (CF₃SNHBNH)₃ are reported. These data are used, together with a qualitative analysis of the bonding situation based on observed rotational barriers and known structures, to analyse for B ← N back donation in these compounds. Relatively small variations in δ^14/15N compared to those observed for alkylaminoboranes as well as large variations in δ¹¹B are suggestive of small contributions only from back bonding. In addition the ?halogene like”? nature of the (CF₃S)₂N group is confirmed. For the series X₂BN(SCF₃)₂ (X = F, Cl, Br on N₃), XB[N(SCF₃)₂]₂ (X = Cl, Br, N₃ or N(SCF₃)₂) and Cl_n?3B(NHSCF₃)_n (n = 1, 2 or 3) a linear relationship for δ¹¹B and δ^14/15N is observed. It is furtheron demonstrated that hitherto known δ^14/15N/¹¹B correlations are valid only in case of strong B ← N back donation.     

Polyfluorinated radical cations

The synthesis of the first trifluoromethanesulfonate esters of the type CF₃SO₃(CH₂)_nO₃SCF₃ (n=1,2,3) are reported. The new compounds are prepared from Cl(CH₂)_nCl by substitutive electrophilic dehalogenation reactions with CF₃SO₂OX (x=Cl,Br). The extension of this reaction to HCCl₃ results in HC(O₃SCF₃)₃ but the compound is unstable at 22°.     

Die Darstellung der Methylthio(trihalogen)phosphonium-Salze ClnBr3−nPSCH3+MF6−(n = 0–3; M = As,Sb) und Hal3PSCH3+SbCl6−(Hal = Br,Cl)

The Preparation of Methylthio(trihalogeno)phosphonium Salts Cl_nBr_3?nPSCH₃⁺MF₆^?(n = 0–3; M = As, Sb) and Hal₃PSCH₃⁺SbCl₆^?(Hal = Br, Cl) The methylthio(trihalogeno) phosphonium salts Br_nCl_3?nPSCH₃⁺MF₆^? (n = 0–3; M = As, Sb) are prepared by methylation of the corresponding thiophosphorylhalides Br_nCl_3?nPS in the system SO₂/CH₃F/MF₅. The hexachloroantimonates Hal₃PSCH₃⁺SbCl₆^?(Hal = Br, Cl) are synthesized by thiomethylation of PBr₃ and PCl₃ with CH₃SCl/SbCl₅. All salts are characterized by vibrational and NMR spectroscopy.     

Darstellung und chemische Eigenschaften von N-Trifluormethylthiophosphaniminen

Preparation and Chemical Properties of N-Trifluoromethylthiophosphaneimines In n-hexane (CF₃S)₃N and (C₆H₅)₃As react to CF₃SN?As(C₆H₅)₃ and CF₃SSCF₃. With (RO)₃P (CF₃S)₃N forms CF₃SSCF₃ and CF₃SN?P(OR)₃ (R = C₆H₅, CH₃, C₂H₅). While CF₃SNP-(OC₆H₅)₃ is stable up to 100°C the other Phosphaneimines rearange to (R′O)₂P(O)N(R′)SCF₃ (R′ = CH₃, C₂H₅). Hydrolysis leads to ROH and (RO)₂P(O)N(H)SCF₃. Only for R = C₆H₅ in addition (C₆H₅O)₂P(O)NH₂ is formed. Physical data and nmr spectra of the newly prepared substances are presented.     

Darstellung und Reaktionen von Selenocarbonyldifluorid und seines cyclischen Dimeren 2,2,4,4-Tetrafluor-1,3-diselenetan [l]

Inhaltsübersicht. Das erstmals hergestellte B(SeCF₃)₃ zerfällt unter dem katalytischen Einfluß von Alkalifluoriden zu F₂C=Se und BF₃. In Anwesenheit von BF₃ polymerisiert F₂CSe bereits. bei ?;80°C. Oberhalb 150°C depolymerisiert (F₂CSe)_n wieder zu F₂C=Se und. Durch Halogenaddition an F₂C = Se gewinnt man F₂XCSeX (X = Cl, Br). Das in der Reihe Cl_3–nF_nCSeCl noch fehlende Cl₂FCSeCl wird durch Umsetzung von CSe₂, ClF und Cl₂ synthetisiert. F_nCl_3–nCSeCl (n = 1. 2) liefert mit Zinn die entsprechenden symmetrischen Diselane, mit AgCN die Selenocyanate. Durch Halogenaustausch mit BX₃ (X = Cl, Br) wird umgewandelt. XC(S)Cl reagiert mit Hg(SeCF₃)₂ zu CF₃SeC(S)X (X = F, Cl. CF₃Se). Daraus werden durch Chloraddition die entsprechenden Sulfenylchloride synthetisiert. IR-NMR- und Massenspektren der neu hergestellten Substanzen werden angegeben. Preparation and Reactions of SeCF₂ and its Cyclic Dimer 2,2,4,4-Tetrafluoro-1,3-diselenetane Abstract. B(SeCF₃)₃, prepared for the first time, decomposes under the influence of alkali metal fluorides to F₂C=Se and BF₃. In presence of BF₃, SeCF₂ polymerizes even at ?80°C. Above 150°C (F₂CSe)n depolymerizes to F₂C = Se and Halogen addition to F₂C=Se produces F₂XCSeX (X = Cl, Br). The compound Cl₂FCSeCl could be synthesized by the reaction of CSe₂ with ClF and Cl₂. These selenenylchlorides react with tin producing the corresponding symmetric diselenides whereas with AgCN the selenocyanates are formed. can be transformed to through halogen exchange reaction with BX₃ (X = Cl, Br). XC(S)Cl reacts with Hg(SeCF₃)₂ to give CF₃SeC(S)X (X = F, Cl. CF₃Se), from which the corresponding sulfenylchlorides can be synthesized by chlorine addition. I.r., n.m.r., and mass spectra of the newly prepared compounds are reported.     

Darstellung und Kristallstrukturen von tBu‐substituierten Disiloxanen des Typus tBu2SiX‐O‐SiYtBu2 (X = Y = OH,Br; X = OH,Y = H) und den Addukten tBu3SiOH·(HO3SCF3)0.5·H2O und tBu3SiOLi·(LiO3SCF3)2·(H2O)2

Syntheses and Crystal Structures of tBu‐substituted Disiloxanes tBu₂SiX‐O‐SiYtBu₂ (X = Y = OH, Br; X = OH, Y = H) and of the Adducts tBu₃SiOH·(HO₃SCF₃)_0.5·H₂O and tBu₃SiOLi·(LiO₃SCF₃)₂·(H₂O)₂ The disiloxanes tBu₂SiX‐O‐SiYtBu₂ (X = Y = H, OH) are accessible from the reaction of CF₃SO₂Cl with tBu₂SiHOH or tBu₂Si(OH)₂. By this reaction the disiloxane tBu₂SiH‐O‐SiHtBu₂ is formed together with tBu₂SiH‐O‐SiOHtBu₂. The disiloxanes tBu₂SiX‐O‐SiYtBu₂ (X = Y = Cl, Br) can be synthesized almost quantitatively from tBu₂SiH‐O‐SiHtBu₂ with Cl₂ and Br₂ in CH₂Cl₂. The structures of the disiloxanes tBu₂SiX‐O‐SiYtBu₂ (X = H, Y = OH; X = Y = OH, Br) show almost linear Si‐O‐Si units with short Si‐O bonds. Single crystals of the adducts tBu₃SiOH·(HO₃SCF₃)_0.5·H₂O and tBu₃SiOLi·(LiO₃SCF₃)₂·(H₂O)₂ have been obtained from the reaction of tBu₃SiOH with CF₃SO₃H and of tBu₃SiO₃SCF₃ with LiOH. According to the result of the X‐ray structural analysis (hexagonal, P‐62c), tBu₃SiOLi · (LiO₃SCF₃)₂·(H₂O)₂ features the ion pair [(tBu₃SiOLi)₂(LiO₃SCF₃)₃(H₂O)₃Li]⁺ [CF₃SO₃]^?. The central framework of the cation forms a trigonal Li₆ prism.     

Über Sn[OCH(CF3)2]2 und Sn (OCH2CF3)2 (n = 1, 2)

On S_n[OCH(CF₃)₂]₂ and S_n(OCH₂CF₃)₂ (n = 1, 2) The sulfoxylates S[OCH(R)CF₃]₂, 1 and 2 and the disulfides S₂[OCH(R)CF₃]₂, 5 and 6 (R = CF₃, H) are obtained by reacting SCl₂ or S₂Cl₂, respectively, and the lithium alcoxides LiOCH(R)CF₃. Chlorine and compound 2 give ClS(O)OCH₂F₃ and CF₃CH₂Cl, whereas the sulfur-sulfur bound is cleaved in 5 and 6 furnishing SCI₂, 1 and 2 , respectively. The ¹⁹F n.m.r. spectrum of 5 and the ¹H n.m.r. spectrum of 6 are interpreted in terms of hindered rotation about the sulfur-sulfur axis.     

Kristallstrukturen und Schwingungsspektren von Tetrahalogenoacetylacetonatoosmaten(IV), [OsX4(acac)]−, X  Cl,Br, I

Crystal Structures and Vibrational Spectra of Tetrahalogenoacetylacetonatoosmates(IV), [OsX₄(acac)]^?, X ? Cl, Br, I By reaction of the hexahalogenoosmates(IV) with acetylacetone the tetrahalogenoacetylacetonatoosmates(IV) [OsX₄(acac)]^? (X = Cl, Br, I) are formed, which have been purified by chromatography and precipitated from aqueous solution as tetraphenylphosphonium (Ph₄P) or cesium salts. X-ray structure determinations on single crystals have been performed of (Ph₄P)[OsCl₄(acac)] ( 1 ) (triclinic, space group P1 , a = 9.9661(6), b = 11.208(2), c = 13.4943(7) Å, α = 101.130(9), β = 91.948(6), γ = 96.348(8)°, Z = 2), (Ph₄P)[OsBr₄(acac)] ( 2 ) (monoclinic, space group P2₁/n, a = 9.0251(8), b = 12.423(2), c = 27.834(2) Å, β = 94.259(7)°, Z = 4) and (Ph₄P)[OsI₄(acac)] ( 3 ) (monoclinic, space group P2₁/c, a = 18.294(3), b = 10.664(2), c = 18.333(3) Å, β = 117.68(2)°, Z = 4). Due to the increasing trans influence in the series O < Cl < Br < I the Os? O^. distances of O^.? Cl? X′ axes are lengthened and the OsO^. stretching vibrations are shifted to lower frequencies. The Os? X′ bond lenghts are shorter as compared with symmetrically coordinated X? Os? X axes.     

Umsetzungen von Thiazylhalogeniden XSN (X = F,Cl) mit perfluorierten Iminen Rf2NH (Rf = F,CF3, CF3S, (CF3)2C, (CF3)2 S): Versuche zur Darstellung von Aminothiazylen (N?SN)

Reactions of Thiazyl Halides XSN (X = F, Cl) with Perfluorinated Imines R_f2 NH (R_f = F, CF₃, CF₃S, (CF₃)₂C?, (CF₃)₂S?): Attempted Preparations of Aminothiazyls (?N? S?N) Thiazyl halides or their precursors Cl₃S₃N₃ and FC(O)N?SF₂ react with perfluoro imines to provide the corresponding aminothiazyls as unstable and reactive intermediates. While with HNF₂ or KF · HNF₂ the final products N₂F₄ and S₄N₄ are formed, [(CF₃)₂N]₂Hg reacts with Cl₃S₃N₃ to give CF₃N?CF₂, FSN, and HgCl₂. The expected product CF₃SN?S?NSCF₃ ( 4 ) is obtained from (CF₃S)₂NH or Hg[N(SCF₃)₂]₂ and FSN probably via (CF₃S)₂ NSN. Surprisingly, (CF₃)₂C?NLi forms with ClSN, Cl₃S₃N₃ or [S₃N₂Cl]Cl in the presence of NH₄Cl 4,5-Dihydro-3,3,5,5-tetrakistrifluoromethyl-3H-1λ⁴,2,4,6-thiatriazine ( 6 ) and (CF₃)₂C?NS_xN?C(CF₃)₂ (X = 1, 2) ( 7a, b ) as byproducts. A CsF catalyzed reaction at 70 to 80°C between (CF₃)₂C?NLi and FSN provides low yields of (CF₃)₂C?N? S? N?S?NCF(CF₃)₂ ( 8 ) together with 7a, b. The latter are the only products without CsF. When (CF₃)₂S?NH is treated with FSN, the compounds CF₃SCF₃, S₄N₄, and N₂ are identified. It is shown by ¹⁹F and ¹⁴N-n.m.r. spectroscopy that (CF₃)S?NSN is an unstable intermediate.     

Hydrolyse und Halogenidaustausch von Pentahalogenomonocarbonylosmaten(III)

Hydrolysis and Halide Exchange of Pentahalogenomonocarbonyl Osmates(III) The aquo complexes [OsX₄(CO)(H₂O)]^?, [OsX₃(CO)(H₂O)] and [OsX₂(CO)(H₂O)₃]⁺, X ? Cl, Br, I, produced by the stepwise hydrolysis of [OsX₅(CO)]^2?, are isolated as pure solutions by ionophoresis and characterized by their absorption spectra. Due to stability of the monaquo complexes and the different trans-effect of the halides it is possible to prepare the mixed complexes [OsX_4–nY_n(CO)(H₂O)]^?, X ≠ Y = Cl, Br, I, n = 1–3, and for n = 2 the pure stereoisomers are formed. A systematic shift is found in charge-transfer bands to the shorter wavelengths when the halides are replaced by H₂O, I by Br or Cl and Br by Cl.     

Oligomere μ-Imidophosphorsäurechloride und -amide

Oligomeric μ-Imidophosphoric Acid Chlorides and Amides Oligomeric μ-imidophosphoric acid chlorides. Cl₂(O)P? [NH? P(O)Cl]_n? Cl, (n = 1, 2, 3) are obtained by solvolysis of the linear phosphorylchlorphosphazenes, Cl₂(O)P? [N?PCl₂]_n? Cl, with the stoichiometric amount of anhydrous formic acid. The chlorides react with ammonia forming the amides. The amides are characterized by paper and gel chromatography. Course and rate of hydrolysis of diimidotriphosphoric acid pentaamide depend on pH.     

Perfluormethyl-element-liganden XII. Zweikernkomplexe des rheniums: Re2(CO)8XY [1]

The reaction of Re₂(CO)₁₀ with E₂(CF₃)₄ (E = P, As) yields the binuclear complexes Re₂(CO)₈[E(CF₃)₂]₂ with two E(CF₃)₂ bridges. The complexes Re₂(CO)₈E(CF₃)₂I (E = P, As) and Re₂(CO)₈As(CF₃)₂Cl, containing two different bridges, are formed in the reactions of Re₂(CO)₁₀ with (CF₃)₂EI (E = P, As) and (CF₃)₂AsCl, respectively. A series of new binuclear complexes is obtained on substitution of iodine in the compounds Re₂(CO)₈E(CF₃)₂I (E = P, As) by SCH₃, SCF₃, SeCF₃, P(CH₃)₂ and H. The binuclear complexes Re₂(CO)₈(E′CF₃)₂ having two E′CF₃ bridges (E′ = S, Se) are obtained reacting Re(CO)₅I With Hg(E′CF₃)₂. At room temperature the mononuclear complex Re(CO)₅SeCF₃ is obtained. Substitution of iodine in Re₂(CO)₈I₂ by SCF₃ also yields the symmetrical compound Re₂(CO)₈(SCF₃)₂; reduction with NaBH₄ gives the binuclear hydride Re₂(CO)₈HJ. - IR and NMR spectra (¹H, ¹⁹F) of the new complexes are reported and discussed.     

Synthese und Eigenschaften linearer Phosphorylchlorphosphazene

Synthesis and Properties of Lineary Phosphorylchlorphosphazenes The phosphorylchlorphosphazenes, Cl₂(O)P—[N?PCl₂]_n—Cl, (n = 1, 2, 3) react like POCl₃ with hexamethyldisilazan forming silylamides, Cl₂(O)P—[N ? PCl₂]_n—NHSi(CH₃)₃, (n = 0, 1, 2, 3). From these are obtained the phosphorylchlorphosphazenes by reaction with PCl₅ containing one group —N ? PCl₂ more.     

Preparation of Tellurium‐Nitrogen containing Moieties in Ionic Chainmolecules,Heterocycles, as well as (CF3Se)2Te, (CF3S)2Se,and (CH3)2Te(X)Y (X = Y = NCO,NSO; X = Cl,Y = NSO)

The reaction between Cl₂Te(NSO)₂, Cl₆Te₂N₂S and Cl₂Te(N=S=N)₂TeCl₂ with MCl₃ provided the compounds [(Cl₂Te)₂N⁺][MCl₄^–] (M = Ga, Al, Fe). Treating Cl₆Te₂N₂S with M′Cl₃ yielded besides [(Cl₂Te)₂N⁺][M′Cl₄^–] (M′ = Al, Fe) the sulfur containing compound [ClTeNSNS⁺][M′Cl₄^–]. The structure for [ClTeNSNS⁺][FeCl₄^–] was established by an X‐ray structure analysis. With Te(NSO)₂ and CF₃SCl, via Cl₂Te(NSO)₂, the known compound Te₂NCl₅ was formed. Tetrafluoroditelluradiazetidine was obtained from TeF₄ and [(CH₃)₃Si]₂NH which on treating with (CH₃)₃SiCl provided the corresponding chloroderivative. In addition metathetical reaction between Cl₂TeNSNS and CF₃C(O)OAg yielded [CF₃C(O)O]₂TeSNSN. Similarly (CH₃)₂Te(NSO)_2–xCl_x (x = 0,1) and (CH₃)₂Te(NCO)₂ were made from (CH₃)₂TeCl₂ and AgNSO or AgNCO, respectively. Halogination of Cl₂Te(N=S=N)₂TeCl₂ with Cl₂ or Br₂ yielded Cl₆Te₂N₂S and Cl₄Br₂Te₂N₂S. The bromoderivate was also prepared from Cl₂Te(NSO)₂ and Br₂. AgNSO was synthesized by treating CF₃C(O)OAg with (CH₃)₃SiNSO. Two other synthons (CF₃Se)₂Te and (CF₃S)₂Se were obtained from CF₃SeCl and Na₂Te and from Hg(SCF₃)₂ plus SeCl₄, respectively.     

Trivalent-pentavalente Phosphorverbindungen/Phosphazene. IV. Darstellung und Eigenschaften neuer N-silylierter Diphosphazene

Trivalent-Pentavalent Phosphorus Compounds/Phosphazenes. IV. Preparation and Properties of New N-silylated Diphosphazenes Phosphazeno-phosphanes, R₃P = N? P(OR′) ₂ (R = CH₃, N(CH₃)₂; R′ = CH₂? CF₃) react with trimethylazido silane to give N-silylated diphosphazenes, R₃P = N? P(OR′)₂ = N? Si(CH₃)₃ compounds decompose by atmospherical air to phosphazeno-phosphonamidic acid esters, R₃ P?N? P(O)(O? CH₂? CF₃)(NH₂). Thermolysis of diphosphazene R₃P = N? P(OR′) ₂ = N? Si(CH₃)₃ (R = CH₃, R′ = CH₂? CF₃) produces phosphazenyl-phosphazenes [N?P(N?P(CH₃)₃)OR′] _n. The compounds are characterized by elementary analysis, IR-, ¹H_-, ²⁹Si-, ³¹P-n.m.r., and mass spectroscopy.     

Darstellung der Halogeno-Pyridin-Rhenate(III), [ReX6−n (Py)n](3−n)− (X = Br,Cl; n = 1−3), sowie Kristallstrukturen von trans-[(C4H9)4N][ReBr4(Py)2], mer-[ReCl3(Py)3] und mer-[ReBr3(Py)3]

Preparation of Halogeno Pyridine Rhenates(III), [ReX_6?n(Py)_n]^(3?n)? (X = Br, Cl; n = 1?3) Crystal Structures of trans-[(C₄H₉)₄N][ReBr₄(Py)₂], mer-[ReCl₃(Py)₃], and mer- [ReBr₃(Py)₃] The mixed halogeno-pyridine-rhenates(III), [ReX_6?n(Py)_n]^(3?n)? (X = Br, Cl), n = 1?3, have been prepared for the first time by reaction of the tetrabutylammoniumsalts (TBA)₂[ReX₆] (X = Br, Cl) in pyridine with (TBA)BH₄ and separation by chromatography on Al₂O₃. Apart from the monopyridine complexes only the trans and mer isomers are formed from the bis-and tris-pyridine compounds. The X-ray structure determinations of the isotypic neutral complexes mer- [ReX₃(Py)₃] (monoclinic, space group P 2₁/n, Z = 4; for X = Cl: a = 9,1120(8), b = 12,5156(14), c = 15,6100(13) Å, β = 91,385(7)°; for X = Br: a = 9,152(5), b = 12,852(13), c = 15,669(2) Å, β = 90,43(2)°) reveal, due to the stronger trans influence of pyridine compared with Cl and Br, that the Re? X distances in asymmetric Py? Re? X3 axes with ReCl3 = 2,397 Å and ReBr3 = 2,534 Å are elongated by 1,3 and 1% in comparison with symmetric X1? Re? X2 axes with ReCl1 = ReCl2 = 2,367 Å and ReBr1 = 2,513 and ReBr2 = 2,506 Å, respectively. The Re? N bond lengths are roughly equal with 2,12 Å. Trans-(TBA)[ReBr₄(Py)₂] crystallizes triclinic, space group P1 , a = 9,2048(12), b = 12,0792(11), c = 15,525(2) Å, α = 95,239(10), β = 94,193(11), γ = 106,153(9)°, Z = 2. The unit cell contains two independent but very similar complex anions with approximate D_2h(mmm) point symmetry.     

Schwingungsspektren und Kraftkonstanten der Übergangsreihen OP(OCH3)3?OPCl3 und SP(OCH3)3?SPCl3

The IR- and RAMAN -spectra are reported from OP(OCH₃)₂Cl, OP(OCH₃)Cl₂, SP(OCH₃)Cl, SP(OCH₃)Cl₂. The assignement to the fundamental vibration is given and all Valence-force-constants are calculated. With increasing number of chlorine atoms decrease f P? OCH₃ and f P? Cl. In the contrary, f O? P and f S? P increase. Here the influence of decreasing electro negativity is compensated by the change from an element of the first period of eight elements to an element of the second period.     

Einkristall-Röntgenstrukturanalysen an Verbindungen mit kovalenter Metall—Metall-Bindung. II. Die Molekül- und Kristallstruktur von X2Sn[Mn(CO)5]2 (XCl,Br) Verbindungen

Single Crystal X-Ray Analysis of Compounds with Covalent Metal–Metal Bonds. II. Molecular and Crystal Structure of X₂Sn[Mn(CO)₅]₂ (X?Cl, Br) Both X₂Sn[Mn(CO)₅]₂ compounds (X?Cl, Br) crystallize in the monoclinic crystal system with at times different values in the lattice parameters. They belong to the space group C_2h⁵. The structures have been solved using 2 107 symmetrical independent reflection for Cl₂Sn[Mn(CO)₅]₂ and 1 470 reflections for Br₂Sn[Mn(CO)₅)₂] by applying the heavy atom method. The following interatomic distances have been found: Cl₂Sn[Mn(CO)₅]₂, Sn? Mn = 2.635(1) Å, Sn? Cl = 2.385(2) Å, Mn? C = 1.852(8) Å, C? O = 1.128(10) Å; Br₂Sn[Mn(CO)₅]₂, Sn? Mn = 2.642(3) Å, Sn? Br = 2.548(2) Å, Mn? C = 1.851(21) Å, C? O = 1.124(25) Å. In addition, bond angles of X? Sn? X and Mn? Sn? Mn of these compounds have also been estimated in the case of X = Cl: 95.80(7)° and 126.25(4)° and for X?Br: 98.44(8)° and 125.88(9)°. The individual molecules of the X₂Sn[Mn(CO)₅]₂ solids are surrounded by ligands showing distorted tetrahedral configuration at the Sn atom and distorted octahedral configuration at the Mn atom.     

Perfluormthyl-Element-Liganden. XVII. Adduktbildung von MenE(CF3)3−n-Liganden mit BX3-Verbindungen (Me = CH3; E = P,As, Sb; n = 0–3; X = H,CH3, Hal)

Perfluoromethyl-Element-Ligands. XVII. Formation of Adducts of Me_nE(CF₃)_3?n Ligands with BX₃ Compounds (Me = CH₃; E = P, As, Sb; n = 0–3; X = H, CH₃, Hal) The ligands Me_nE(CF₃)_3?n (Me = CH₃; E = P, As, Sb; n = 0–3) have been prepared (partly using new methods) and studied by n.m.r. spectroscopy (¹H, ¹⁹F, ³¹P, ¹³C). In order to deduce their relative donor strength their reactions with the Lewis acids “BH₃”, BMe₃, BMe₃, Me₂BBr, and BX₃ (X = F, Cl, Br) have been studied. Control of adduct formation occurs by n.m.r. spectroscopy (¹H, ¹⁹F). The following series of decreasing basicity or acidity are obtained: