Darstellung und strukturen von cyclischen tristanna-dichalkogen-verbindungen

Cyclic tin chalcogen compounds with tintin bonds (t-Bu₂Sn)₃Y₂ (Y  S, Se, Te) have been prepared starting with (t-Bu₂Sn)₄ or (t-Bu₂SnY)₂. X-Ray analysis shows planar five-membered tin-sulfur rings and tin-selenium rings. The structure of the tellurium compound consists of puckered molecules with C₂ symmetry and a somewhat shorter tintin bond.     

Synthese und spektroskopische Untersuchungen von Di-t-Butylzinn(IV)-dicarboxylaten

Synthesis and Spectroscopic Studies of Di-t-butyltin(IV) dicarboxylates Five Di-t-butyltin(IV) dicarboxylates t-Bu₂Sn(O₂CR)₂ (R ? CH₃, C(CH₃)₃, C₆H₅, C₆H₄NH₂-2, C₅H₄N-2) have been synthesized by reaction of Di-t-butyltinoxide (t-Bu₂SnO)₃ with corresponding ligands and studied by ¹H-, ¹³C-, ¹¹⁹Sn n.m.r. and infrared spectroscopy. The compounds are monomeric in CD₂Cl₂- or CDCl₃-solution and have pentacoordinated tin atoms with exception of the picolinate. The coordination takes place through the carboxylic oxygen atoms. In the Di-t-butyltin(IV)di-2-picolinate the tin atom is hexacoordinated by intramolecular tin-nitrogen-interaction.     

Multiple bond migration with participation of a protophilic agent

The pathways of migration of the double bond in heteroallylic systems XCH₂CH=CH₂ (X =NMe₂, OMe, PMe₂, and SMe) with participation of hydroxide ion were investigated by theab initio RHF/6-31+G^* and MP2/6-31+G^* methods. The results are compared with those of analogous calculations of the systems with X=H, Me. Conformational isomerism of the initial molecules and reaction products, as well as the structure of intermediate carbanions, are considered. Increased acidity of compounds containing atoms of the third-row elements is explained in terms of a negative hyperconjugation model, 1,3-Hydrogen shift with participation of hydroxide ion in the system XCH₂CH=CH₂ results in double bond migration toward substituent X to form 1-hetero-1-propenes XCH=CHMe. Comparison of the energies of the final products indicates thermodynamic preferableness of the formation ofE-isomers. At the same time, in the case of substituents with atoms of the second-row elements the interaction of σ-bonds of the substituents and the p-AO of the terminal C atom additionally stabilizesZ-isomers of the carbanions and can be the reason for preferable kinetically controlled formation of these isomers. If the subsituents contain atoms of the third-row elements, the formation ofE-isomers of 1-hetero-1-propenes becomes both kinetically and thermodynamically predominant.     

Etude théorique par la méthode DFT des structures non-classiques des systèmes X2H2F2 (X=Si, Ge, Sn)

The structure and the relative stability of isomers of molecules X₂H₂F₂ (X=Si, Ge, Sn) have been studied using the density functional theory (DFT). We have determined the optimised structures of the substituted isomers. The XX bond have been studied and compared to that of the parent molecules: X₂H₄. It appears that, for the planar and trans ethylenic systems, the double bond character of the XX decreases when the hydrogen atoms are substituted by fluorine atoms. The most stable structure is shown to be the one where the two fluorine atoms are fixed on the same atom. The bridged structures are also studied.     

Cyclometalation at carbon adjacent to oxygen in platinum(II) and iridium(I) phosphine complexes

Heating trans-PtCl₂(t-Bu₂PCH₂OCH₃)₂ at 125°C in 2-methoxyethanol yields a cyclometalated derivative, P$\text{tCl(t-Bu}{}_2\text{PCH}{}_2\text{OCH}$₂)(t-Bu₂PCH₂OCH₃). Adding excess NaI and 1,8-bis(dimethylamino)naphthalene accelerates the reaction and gives the iodide-substituted analog. Under the same conditions, trans-PtCl₂(t-Bu₂POCH₂CH₃)₂ is also metalated at the methyl carbon atom. However, the slower rate of this reaction indicates that an α-oxygen atom has an electronic accelerating effect on the metalation process. Neither t-Bu₂POCH₃ nor t-Bu₂PCH₂CH₂OCH₃ give platinum(II) cyclometalated complexes; four- or six-membered chelate ring formation appears to be unfavorable. The t-Bu₂PCH(CH₃)OCH₃ ligand also does not yield a platinum(II) metalated derivative. However, [IrCl(COT)₂]₂ (COT = cyclooctene) reacts at 25°C with both t-Bu₂PCH₂OCH₃ and t-Bu₂PCH(CH₃)OCH₃, to form iridium(III) metalated complexes by oxidative addition to the methyl CH bond. These coordinatively unsaturated compounds react with CO, yielding octahedral iridium(III) carbonyl hydride complexes.     

Synthese,Charakterisierung und Struktur von P7(t-Bu3Si)3 („Tris(supersilyl)heptaphosphan(3)”︁)

Synthesis, Characterization, and Structure of P₇(t-Bu₃Si)₃ (?Tris(supersilyl)heptaphosphane(3)”? Tris(tri-tert-butylsilyl)heptaphosphanortricyclane P₇(t-Bu₃Si)₃ 1 is obtained from the reaction of (t-Bu)₃Si? Si(t-Bu)₃ with white phosphorus and forms colorless to pale yellow thermostable crystals. 1 is identified by the complete analysis of its ³¹P{¹H} NMR spectrum (A[MX]₃ spin system) as well as by a single crystal structure determination (space group Pca2₁, a = 170.76(2)pm, b = 131.14(3)pm, c = 426.61(5)pm, α = β = γ= 90°, Z = 8 formula units in the elementary cell). The steric demand of the (t-Bu)₃Si-Groups causes an increase of the exocyclic bond angles at the equatorial phosphorus atoms P^e, while it does not particularly influence the P₇-skeleton. Chlorine (r.t.) and bromine (70°C) degrade the P₇-cage of 1 with formation of PX₃ and (t-Bu)₃SiX (X = Cl, Br).     

The directed synthesis and the spectral and magnetic characteristics of a new multispin (S=7/2,T=292 K) trinuclear complex

The new trinuclear complex K{(CoTp^t-Bu)[Fe(CN)₆](CoTp^t-Bu)}, in which the initial structural fragments are linked by CN⁻ bridges, was synthesized by the directed stitching of mononuclear complexes, one of which was [Fe(CN)₆]³⁻ while the other was cobalt(II) tris(3-tert-butyl-l-pyrazolyl)borate ([(CoTp^t-Bu)]⁺). The magnetic moment of K{(CoTp^t-Bu)[Fe(CN)₆](CoTp^t-Bu)} at 292 K was 8.07 μ_β (S=7/2), indicating the absence of antiferromagnetic exchange interactions in the trinuclear complex. Translated from Teoreticheskaya i éksperimental'naya Khimiya, Vol. 34, No. 6, pp. 351–354, November–December, 1998.     

Dicopper(II) trihydroxide cyanoureate dihydrate

The title compound, poly[[μ‐cyanoureato‐tri‐μ‐hydroxido‐dicopper(II)] dihydrate], {[Cu₂(C₂H₂N₃O)(OH)₃]·2H₂O}_n, is a new layered copper(II) hydroxide salt (LHS) with cyanoureate ions and water molecules in the interlayer space. The three distinct copper(II) ions have distorted octahedral geometry: one Cu (symmetry ) is coordinated to six hydroxide groups (4OH + 2OH), whilst the other two Cu atoms (symmetries and 1) are coordinated to four hydroxides and two N atoms from nitrile groups of the cyanoureate ions (4OH + 2N). The structure is held together by hydrogen‐bonding interactions between the terminal –NH₂ groups and the central cyanamide N atoms of organic anions associated with neighbouring layers.     

[t-Bu2P]3P7 und (t-Bu2Sb)3P7 sowie Untersuchungen zur Bildung von Heptaphosphanen(3) mit PMe2-, PF2- und P(CF3)2-Gruppen

[t-Bu₂P]₃P₇ and (t-Bu₂Sb)₃P₇, as well as Investigations on the Formation of Heptaphosphanes (3) Containing PMe₂, PF₂, and P(CF₃)₂ Groups Tris(di-tert-butylphospha)heptaphosphanortricyclane (t-Bu₂P)₃P₇ 1 obtained by reacting Li₃P₇ · 3 DME with t-Bu₂PF forms yellow crystals. (t-Bu₂Sb)₃P₇ 2 produced similarly from t-Bu₂SbCl and Li₃P₇ · 3 DME didn't form crystals; it decomposes in a solution of toluene above ?10°C. Both compounds were identified by their ³¹P{¹H} NMR spectra, and 1 also by elemental analysis and single crystal structure determination (space group) P2₁/a, a = 1 712.0(9) pm, b = 1 105.1(7) pm, c = 1 854.0(10) pm, β = 94.96(4)°, Z = 4 formula units in the elementary cell). Attempts to synthesize (Me₂P)₃P₇ 3 , (F₂P)₃P₇ 4 and [(F₃C)₂P]₃P₇ 5 failed as dialkylchlorophosphanes as Me₂PCl e. g. with Li₃P₇ · 3 DME react under Li/Cl exchange, dialkylfluorophosphanes (except t-Bu₂PF) disproportionate, and neither PF₃ nor (F₃C)₂PBr with Li₃P₇ · 3 DME give the desired products 4 or 5 , resp.     

Organometallic Reactions and Syntheses : Volume 6, E. I. Becker and M. Tsutsui,ed., Plenum Publishing Corporation., New York/ London, 1977, xii + 314 pages $47.40

The (Me₃Si)₃C group causes very large steric hindrance to nucleophilic displacement at a silicon atom to which it is attached, and (Me₃Si)₃CSiMe₂Cl is even less reactive than t-Bu₃SiCl towards base. The compounds (Me₃Si)₃CSiMe₂X (X = Cl, Br, or I) are cleaved by MeOH/MeONa to give (Me₃Si)₂CHSiMe₂OMe, possibly via the silaolefin (Me₃Si)₂ CSiMe₂, and the correspondLug (Me₃Si)₃ CSiPh₂X compounds undergo the analogous reaction even more readily. The halides (Me₃Si)₃CSiR₂X (X = Cl or Br) and (Me₃Si)₃CSiCl₃ do not react with boiling alcoholic silver nitrate, but the iodides (Me₃Si)₃CSiR₂I are rapidly attacked.     

Crystal Structures of [Cu2(bpy)2(H2O)(OH)2(SO4)]·4H2O and [Cu(bpy)(H2O)2]SO4 with bpy = 2, 2′‐Bipyridine

Two sulfato Cu^II complexes [Cu₂(bpy)₂(H₂O)(OH)₂(SO₄)]· 4H₂O ( 1 ) and [Cu(bpy)(H₂O)₂]SO₄ ( 2 ) were synthesized and structurally characterized by single crystal X—ray diffraction. Complex 1 consists of the asymmetric dinuclear [Cu₂(bpy)₂(H₂O)(OH)₂(SO₄)] complex molecules and hydrogen bonded H₂O molecules. Within the dinuclear molecules, the Cu atoms are in square pyramidal geometries, where the equatorial sites are occupied by two N atoms of one bpy ligand and two O atoms of different μ₂—OH groups and the apical position by one aqua ligand or one sulfato group. Through intermolecular O—H···O and C—H···O hydrogen bonds and intermolecular π—π stacking interactions, the dinuclear complex molecules are assembled into layers, between which the hydrogen bonded H₂O molecules are located. The Cu atoms in 2 are octahedrally coordinated by two N atoms of one bpy ligand and four O atoms of two H₂O molecules and two sulfato groups with the sulfato O atoms at the trans positions and are bridged by sulfato groups into ¹[Cu(bpy)(H₂O)₂(SO₄)_2/2] chains. Through the interchain π—π stacking interactions and interchain C—H···O hydrogen bonds, the resulting chains are assembled into bi—chains, which are further interlinked into layers by O—H···O hydrogen bonds between adjacent bichains.     

An ab initio evaluation of the role of p,π interaction: I. Ethylene derivatives

The RHF/6-311G(d) and MP2/6-311G(d) calculations with full geometry optimization were performed for XCH=CH₂ molecules (X = F, Cl, Br, CH₃, CH₂CH₃, CH₂F, CHO). The p _y electron density distribution in these molecules and the bonding molecular orbitals formed by the p _y orbitals of atoms of the planar fragment of these molecule (atomic orbitals whose symmetry axes are perpendicular to this plane) are not determined by the p,π conjugation between the lone electron pair of the heteroatom in substituent X and π electrons of the C=C bond. Changes in the population of the p _y orbitals of the halogen and carbon atoms in going from X = F to X = Cl and Br are not associated with changes in the extent of this p,π interaction. Taking into account the electon correlation in the MP2 method does not noticeably alter the features of the electron density distribution in these molecules estimated by restricted Hartree-Fock calculations.     

Über polystannane: II. I(t-Bu2Sn)4I,ein 1,4-difunktionelles tetrastannan

The compound I(t-Bu₂Sn)₄I has been synthesized by controlled cleavage of the related cyclotetrastannane (t-Bu₂Sn)₄ with iodine in toluene. Both compounds have been investigated by mass, NMR and vibrational spectra. I(t-Bu₂Sn)₄I: δ(¹¹⁹Sn_terminal) 67.7, δ(Sn_central) 17.4 ppm; ¹J(SnSn) 2199 (terminal-central) and 1575 (central-central), ²J(SnSn) 20 (terminal-central), ³J (SnSn) 307 Hz (terminal-terminal); ν(SnSn) 119, ν(SnI) 167 cm^?1. (t-Bu₂Sn)₄: δ(Sn) 87.4 ppm; ν(SnSn) 125 cm^?1. The crystal structure of I(t-Bu₂Sn)₄I has been determined (R = 0.071): bond lengths SnSn 289.5(1) (terminal-central) and 292.4(1) (central-central), SnI 275.3(1) pm. The conformation of the chain ISn₄I is all trans.     

Identification of molecules in inorganic compounds from X-ray or neutron diffraction data and correction of their structures on the basis of vibrational spectroscopy data

A method of identification of molecules in inorganic crystals with asymmetric M-X...M bridges has been suggested on the basis of analysis of interatomic distances in the structure unit M (−X...M) _n , which includes the atoms of the first and second coordination spheres. This analysis makes it possible to discern molecules (complex anions or cations) as a groups of atoms linked with each other by short M-X bonds, whereas the atoms of neighboring groups are linked by long M...X bonds. The symmetry of such a group is often lower than it follows from X-ray or neutron diffraction data. Studying vibrational spectra affords information on the true symmetry of a molecule. The use of the method is exemplified by the rhombohedral BaTiO₃ phase.     

Trichloro-bridged diruthenium (III,III) complexes: X-ray isomorphous structures of [Ph3X=O···H···O=XPh3][Ru2Cl7(XPh3)2]·0.5(CH2Cl2)(H2O)(X = As or P)

The triply chloro-bridged binuclear complexes [Ph₃X=O···H···O=XPh₃][Ru₂Cl₇(XPh₃)₂]·0.5(CH₂Cl₂)(H₂O) (X = As or P) were obtained from [RuCl₃(XPh₃)₂DMA]·DMA (DMA = dimethylacetamide) CH₂Cl₂/Et₂O solution. The structures were characterized by X-ray diffraction studies. The complexes are formed from two Ru atoms bridged by three chloride anions. The two ruthenium atoms are also coordinated to two non-bridging Cl atoms and an AsPh₃ or PPh₃ ligand respectively. As an interesting feature, the cations of these complexes are protons, trapped in a very short hydrogen bond between two triphenylarsine or triphenylphosphine oxide molecules.     

Syntheses and Structures of Acetyl‐Acetonato‐Alumo‐Diphenylsilanolates with Magnesium(II), Iron(II), Iron(III), Cobalt(II), and Nickel(II)

Bis(acetylacetonate)alumo‐oxo‐tetraphenyldisiloxane‐metal(II) dihydrates [(acac)₂Al(O–SiPh₂–O–SiPh₂–O)]₂M(H₂O)₂ (M = Mg, Fe, Co, Ni) were obtained from the corresponding acetyl‐acetonate‐dihydrates (acac)₂M(H₂O)₂ by reaction with the alumosiloxane [O–Ph₂Si–O–SiPh₂–O]₄Al₄(OH)₄. These new compounds display two acac ligands at the aluminum atoms as well as disilatrioxy chains linking the two aluminum atoms forming a (Al–O–Si–O–Si–O)₂ cycle (X‐ray structure analyses). Within this cycle the divalent metal ions M²⁺, to which two water molecules in trans positions are linked, are installed in almost planar MO₄ coordination spheres. Using water free (acac)₂Ni a different product forms: both reactants combine in a 2:1 ratio to yield [O–Ph₂Si–O–SiPh₂–O]₄Al₄(OH)₂O(OH₂)Ni₂(acac)₄. Here, three of the acac ligands were transposed to the aluminum atoms. The nickel atoms are in a distorted octahedral coordination mode from oxygen atoms of the ligands. When iron(III)tris(acetylacetonate) reacts with the alumosiloxane [O–Ph₂Si–O–SiPh₂–O]₃Al₂O(OH)Fe₂(acac)₃ was isolated, in which the two iron atoms still display one of the acac ligands. One of the aluminum atoms is in a tetrahedral oxygen environment, whereas the other is in the center of a trigonal bi‐pyramid formed of oxygen atoms either of the siloxane or of acac. The iron atoms have five‐ or sixfold coordination from oxygen atoms of siloxane, acac, hydroxide or oxide.     

The crystal structure of t-Bu2Si(OH)F. A cyclic hydrogen-bonded tetramer

An X-ray diffraction study has shown that t-Bu₂Si(OH)F crystallizes as hydrogen-bonded tetramers. The fluoride ligand does not take part in the hydrogen bonding, which involves OH--O linkages with an OH--O angle of 160°; the O---O---O angles are 89.7(3)°, but the four oxygen atoms are not quite coplanar (space group I$\text{4}$). The t-BuSiBu-t angle is 120.5(6)°.     

Bis[tris(cyclohexyl)tin] azide hydroxide, (Cy3Sn)2N3(OH): X‐ray structure determination and comparison with analogous compounds

The structure of bis[tris(cyclohexyl)tin] azide hydroxide, (Cy₃Sn)₂N₃(OH) ( 1 ), contains infinite chains of molecules linked by regularly alternating and µ₂ bridging azide and hydroxide groups that create trigonal bipyramidal tin centres. The bridges, with Sn? N 2.436(11) and 2.385(11) Å and Sn? O 2.199(8) and 2.197(8) Å, are relatively symmetrical. This structure is similar to that of catena bis(trimethyltin) azide hydroxide, (Me₃Sn)₂N₃(OH) ( 2 ). In the structure of 1 , each terminal nitrogen atom of the azide is bonded to a different tin atom (1,3 or α,γ bridge formation). In the structure of 2 , however, only one nitrogen atom of each azide is involved in bridging and bonds to two different tin atoms (1,1 or α,α bridge formation). In this case, the remaining terminal nitrogen atoms act as acceptors for O? H?N hydrogen bonds that link the chains to form infinite sheets. It appears then, from these two examples, that in such compounds the size of the organic species bonded to tin can affect the azide bridging mode and also the packing of the polymeric chains Copyright © 2005 John Wiley & Sons, Ltd.     

Komplexchemie P-reicher Phosphane und Silylphosphane. IV. Bildung und Struktur der Chromcarbonylkomplexe des Tris(di-tert-butylphospha)heptaphosphanortricyclans, (t-Bu2P)3P7

Transition Metal Complexes of P-rich Phosphanes and Silylphosphanes. IV. Formation and Structure of the Chromium Carbonyl Complexes of Tris(di-tert-butylphospha)heptaphosphanortricyclane (t-Bu₂P)₃P₇ The reaction of (t-Bu₂P)₃P₇ 1 with Cr(CO)₅ · THF in a molar ratio of 1:1 yields yellow crystals of (t-Bu₂P)₃P₇[Cr(CO)₅] 2 having the Cr(CO)₅ group coordinated to a P^b atom (basal) of the three membered ring. With a molar ratio of 1:2 compounds 2 , (t-Bu₂P)₃P₇[Cr(CO)₅]₂ 3 , (t-Bu₂P)₃P₇[Cr(CO)₅][Cr(CO)₄] 4 and (t-Bu₂P)₃P₇[Cr(CO)₄]₂ 5 were obtained. In 3 (yellow crystals) one Cr(CO)₅ group is linked to a P^b atom, the other one to an exocyclic P^exo atom. On irradiation 3 loosing one CO group generates 4 (orange red crystals) with an unchanged Cr(CO)₅ group linked to the Pb atom and a five membered chelate-like ring containing an apical Pa atom, two equatorial P^a atoms, one P^exo atom and the Cr atom of the carbonyl group. Compound 5 (orange red crystals) contains two such five membered rings. (t-Bu₂P)₃P₇[Cr(CO)₄]₃ 6 (red needles) is formed with Cr(CO)₅ · THF in a molar ratio of 1 : 1. However, even with higher amounts of Cr(CO)₅ · THF and after extended reaction times, only 6 is formed; no further Cr carbonyl group could be attached to the P skeleton. With Cr(CO)₅ · NBD in a molar ratio of 1 : 1, (t-Bu₂P)₃P₇[Cr(CO)₄] 7 is produced from 1, and 5 with a molar ratio of 2 : 1. As in 4, the Cr(CO)₄ group in 7 (orange crystals) participates in a five membered chelate-like ring. It was not possible to generate 6 from 5 with an excess of Cr(CO)₄ · NBD and with extended reaction times. The molecular structures of the compounds were identified by investigating the ³¹P[¹H] NMR spec-tra and considering especially the coordination shift, and by crystal structure determinations of 2 and 4. Compound 2 crystallizes in the space group PI (no.2) with a = 1566.2(4) pm, b = 2304.1(5) pm, c = 1563.3(4) pm,α = 95.57(3)°, β = 108.79(3)°, γ = 109.82(4)° and Z = 4 formula units in the elementary cell. Compound 4 crystallizes in the space group P 2₁ /n (no. 14) with a = 1416.6(5) pm, b = 2573.6(5) pm, c = 1352.9(4) pm,β = 99.17(5)° and Z = 4 formula units in the elementary cell.     

Some complexes of rhodium and iridium with 2-(di-t-butylphosphinomethyl)-1-methoxy-4-methylbenzene

Summary The new tertiary phosphine t-13u₂(2-MeO-5-MeC₆H₃CH₂)P, L, was prepared by the base treatment of the phosphonium salt, LH⁺I^–, which was in turn prepared from t-Bu₂PH, 2-MeO-5-MeC₆H₃CH₂Cl and sodium iodide. This phosphine, L, reacts with various chloro-rhodium and -iridium species without O-demethylation. This contrasts with the behaviour of t-Bu₂PC₆H₄OMe-2 which demethylates readily on similar treatment to give chelate complexes. The completely different behaviour between this new 2-methoxybenzylphosphine, L, and the 2-anisylphosphine, t-Bu₂PC₆H₄OMe-2, is explained in terms of steric effects.No reprints are available.