7‐Phenyl‐1‐oxa‐4‐thiaspiro[4.5]decan‐7‐ol stereoisomers

The stereoisomers of 7‐phenyl‐1‐oxa‐4‐thia­spiro­[4.5]­decan‐7‐ol, C₁₄H₁₈O₂S, have the same stereochemistry at the C atom bearing an OH group, i.e. axial OH and equatorial phenyl groups. However, the acetal S and O atoms are axial and equatorial, respectively, in one isomer and reversed in the second. Furthermore, the crystals of one isomer are composed of hydrogen‐bonded mol­ecules involving the hydroxyl H atom and the O atom of the five‐membered heterocyclic ring, with an O?O distance of 2.962 (3) Å, forming a polymeric chain along the b axis. The asymmetric unit of the other isomer is composed of two mol­ecules, wherein hydroxyl H atoms and the O atoms of the five‐membered heterocyclic rings display intramolecular O—H?O hydrogen bonds with O?O separations of 2.820 (2) and 2.834 (2) Å.     

One‐dimensional uranium–organic framework in catena‐poly[[di‐μ2‐hydroxido‐bis[dioxouranium(VI)]]‐di‐μ2‐2‐pyridylacetato‐κ3O,N:O′;κ3O:O′,N]

In the title compound, {[UO₂(C₇H₆NO₂)(OH)]}_n, the U atom is in a seven‐coordinated pentagonal–bipyramidal environment. Each uranyl ion is bound to the N and one of the O atoms of a 2‐pyridylacetate ligand, to one O atom from a second ligand and to two bridging hydroxide groups, all located in the equatorial plane. Hydroxide bridging gives uranyl dimers, which are assembled into planar and rectilinear ribbons by carboxylate bridges. 12‐Membered rings are defined by proximal dimers in the ribbons, with two intra‐ring hydrogen bonds involving the hydroxide groups and two carboxylate O atoms.     

Pentacarbonyl(di‐2‐pyridyl­amine)tungsten(0)

In the title molecular complex, (I), the W atom is in an octahedral environment with four equatorial carbonyl ligands and a fifth in an axial position trans to the monodentate dipyridyl­amine ligand. The long dimension of this last bisects the angle between two of the equatorial carbonyl groups and while the non‐bonded pyridyl N atom is directed away from the W atom, the bridging amine group is directed towards it. Thus, in addition to the N atom to which it is attached, the amino H has two nearest neighbour C atoms of equatorial carbonyl groups but does not participate in hydrogen bonding in any real or usual sense. The W—C bond distance for the axial carbonyl group is notably less than those of the equatorial groups.     

The chloro­(diethyl­amino)­di­methyl­tin dimer

The title compound, di‐μ‐diethyl­amido‐N:N‐bis­[chloro­di­methyl­tin(IV)], consists of discrete [Sn₂Cl₂(CH₃)₄(C₄H₁₀N)₂] dimer mol­ecules, with Sn atoms linked by bridging diethyl­amido groups. The coordination geometry about the metal atom is distorted trigonal bipyramidal, with the two methyl C atoms and one N atom in the equatorial plane, and the Cl and second N atom in axial positions.     

Elimination of water from the molecular ion of cycloheptanol

Under electron impact cycloheptanol decomposes by four fragmentation paths: (1) α-cleavage with subsequent losses of C¹-C⁵ fragments, (2) elimination of water, (3) loss of the hydrogen atom from C-1 and (4) loss of the hydroxyl group. The mechanism of water elimination was investigated by means of deuterium labelling. 1,4-Elimination of water predominates in cycloheptanol, with the stereospecific cis-1,3-elimination also being operative. The loss of water is preceded by extensive exchange of the hydroxyl hydrogen with those of the ring. This is attributed to a very facile transannular interaction of the hydroxyl group with the C-3 to C-6 positions that are made accessible due to conformational properties of the 7-membered ring. A kinetic model is proposed, describing migrations of the ring hydrogen atoms.     

(2,6‐Bis{1‐[4‐(dimethylamino)phenylimino]ethyl}pyridine)dichlorido(triphenylphosphine‐κP)ruthenium(II): a zigzag chain of fused centrosymmetric R22(12) rings

The title compound, [RuCl₂(C₂₅H₂₉N₅)(C₁₈H₁₅P)], a transfer hydrogenation catalyst, is supported by an N,N′,N′′‐tridentate pyridine‐bridged ligand and triphenylphosphine. The Ru^II centre is six‐coordinated in a distorted octahedral arrangement, with the two Cl atoms located in the axial positions, and the pyridine (py) N atom, the two imino N atoms and the triphenylphosphine P atom located in the equatorial plane. The two equatorial Ru—N_imino distances (mean 2.093 Å) are substantially longer than the equatorial Ru—N_py bond [1.954 (4) Å]. It is observed that the N_imino—M—N_py bond angle for the five‐membered chelate rings of 2,6‐bis(imino)pyridine‐based complexes is inversely related to the magnitude of the M—N_py bond. The title structure is stabilized by intra‐ and intermolecular C—H...Cl hydrogen bonds, as well as by intramolecular π–π stacking interactions between the aromatic rings belonging to the triphenylphosphine ligand and the dimethylaminophenyl fragment. The intermolecular hydrogen bonds form an R₂²(12) ring and a zigzag chain of fused centrosymmetric rings running parallel to the [100] direction.     

Synthesis and Structure of the First Terminal Borylene Complexes

A nearly linear arrangement is observed for the three atoms in the central W-B-N unit of the tungsten complex [(CO)₅WBN(SiMe₃)₂] ( 1 ) in the crystal (W-B-N 177.9°; see picture). This compound along with its Cr analogue represent the first examples of terminal borylene complexes with a two-coordinate metal-bound boron atom. The geometries of the axial and equatorial CO groups in 1 are similar, and thus indicate that there is no trans effect of the borylene ligand.     

POLYMERIC MOLECULAR PATTERN IN THE CRYSTALS OF A CALCIUM(II) COMPLEX WITH PYRIDINE-3,4-DICARBOXYLATE AND WATER LIGANDS

Abstract

Crystals of triaquamono (μ-pyridine-3,4-dicarboxylato-O,O′,O,O′)(aqua-O)calcium(II) contain molecular ribbons in which two adjacent calcium ions are bridged via oxygen atoms donated by the carboxylate group attached to carbon atom “3” in the pyridine ring. Both oxygen atoms are bidentate, each being coordinated to two caloium ions. In addition, every second pair of calcium(II) ions is bridged by a water oxygen atom. The coordination polyhedron around the calcium(II) ion is pentagonal bipyramidal; its equatorial plane is composed of two bridging oxygen atoms each belonging to the carboxylate group of the adjacent ligands, the bridging water oxygen atom and two coordinated water molecules. Another coordinated water oxygen atom constitutes the apex of the pyramid on one side of the pentagon, while two bridging carboxylate oxygen atoms donated by the same carboxylate group make two apices on the other side of the pentagon. The pyridine hetero-ring nitrogen atom does not participate in coordination to the central ion. Both oxygen atoms of the carboxylate group attached to the carbon atom in position “4” of the pyridine ring are not directly coordinated to the calcium(II) ion and act only as acceptors in the hydrogen bond system.     

Crystallographic report: Polymeric [3‐(triphenylgermyl)‐3‐o‐methoxyphenylpropionato]trimethyltin(IV)

The polymeric chains of [Sn(CH₃)₃(C₂₈H₂₅O₃Ge)]_n contain trimethyltin moieties bridging two neighboring 3‐(triphenylgermyl)‐3‐o‐methoxypropionate ligands via carboxyl groups. The germanium atom has a distorted tetrahedral geometry and the tin atom has a distorted trigonal‐bipyramidal geometry, the latter with three methyl groups in the equatorial plane and oxygen atoms defining the axial positions. Copyright © 2005 John Wiley & Sons, Ltd.     

Conformation of N‐methyl‐4‐piperidyl 2,4‐dinitrobenzoate

The crystal structure of N‐methyl‐4‐piperidyl 2,4‐di­nitro­benzoate, C₁₃H₁₅N₃O₆, (I), at 130 (2) K reveals that, in the solid state, the mol­ecule exists in the equatorial conformation, (Ieq). Thus, the through‐bond interaction present in the axial conformation, (Iax), is not strong enough to overcome the syn–diaxial interactions between the axial methyl substituent and the axial H atoms on the two piperidyl ring C atoms either side of the ester‐linked ring C atom. The carboxyl­ate group in (I) is orthogonal to the aromatic ring, in contrast with other 2,4‐di­nitro­benzoates, which are coplanar. The piperidyl–ester C—O bond distance is 1.467 (3) Å, which is actually shorter than other equatorial cyclo­hexyl–ester C—O distances. This shorter piperidyl–ester C—O bond distance is due to the reduced electron demand of the orthogonal ester group.     

catena‐Poly­[[[aqua(2‐methyl‐4‐oxo‐4H‐pyran‐3‐olato‐κO3,O4)copper(II)]‐μ‐chloro] monohydrate]

In the title complex, {[Cu(C₆H₅O₃)Cl(H₂O)]·H₂O}_n, the Cu^II atom has a deformed square‐pyramidal coordination geometry formed by two O atoms of the maltolate ligand, two bridging Cl atoms and the coordinated water O atom. The Cu atoms are bridged by Cl atoms to form a polymeric chain. The deprotonated hydroxyl and ketone O atoms of the maltolate ligand form a five‐membered chelate ring with the Cu atom. Stacking interactions and hydrogen bonds exist in the crystal.     

Unique Bora[1]ferrocenophanes with Sterically Protected Boron: A Potential Gateway to Helical Polyferrocenes

Silicon‐bridged [1]ferrocenophanes are a versatile class of monomers to obtain well‐defined metallopolymers, however, their boron‐bridged analogues are far less utilized despite being significantly higher strained. We assumed that the reactivity of known bora[1]ferrocenophanes towards ring‐opening polymerization is hampered by π‐donating R₂N groups at the bridging boron atom and therefore prepared the first bora[1]ferrocenophanes lacking such electronic stabilization. The new, isolated ferrocenophane with a 2,4,6‐triisopropylphenyl group attached to the bridging boron atom exhibits the most tilted Cp rings among all isolated strained sandwich compounds [α(DFT)=33.3°] with a measured record value of the bathochromic shift (λ_max=516 nm). Attempts to purify the mesityl analogue by vacuum sublimation transformed this monomer to a purple‐colored polymer that resulted in Cotton effects in circular dichroism spectroscopy. DFT calculations revealed a left‐handed helical structure for this polymer. This is the first evidence for a polyferrocene with a chiral secondary structure.     

(1S,2R,2′S)‐ and (1S,2S,2′S)‐1‐phenyl‐2‐phenyl­thio‐2‐(tetra­hydro­pyran‐2′‐yl­thio)­ethanol diastereoisomers at 193 K

In the synthesis of 1‐phenyl‐2‐phenyl­thio‐2‐(tetra­hydro­pyran‐2‐yl­thio)­ethanol, C₁₉H₂₂O₂S₂, four diastereoisomers are formed. Two non‐centrosymmetric enantiomeric forms which crystallize in space groups P2₁2₁2₁ and Pna2₁ are presented. The former has an intramolecular hydrogen bond between the hydroxyl group and the O atom of the tetra­hydro­pyran ring. In the latter isomer, the hydroxyl group forms an intermolecular hydrogen bond to the O atom of the tetra­hydro­pyran­yl group of a neighbouring mol­ecule, joining the mol­ecules into chains in the c‐axis direction; the O?O distances are 2.962 (4) and 2.764 (3) Å, respectively. The tetra­hydro­pyran rings are in chair conformations in both isomers and the S side chain has an equatorial orientation in the former, but an axial orientation in the latter mol­ecule.     

Stereochemical aspects of proton chemical shifts. VI—increments due to geminal hydroxyl,methyl substitution

In geminal methyl, hydroxyl substitution an axial hydroxyl, equatorial methyl arrangement has a downfield effect on a syn axial hydrogen atom which is larger by 0.3 ppm than an axial methyl, equatorial hydroxyl arrangement. It is proposed that these observations may constitute a basis for configurational assignment.     

Conformational Behaviour of Substituted 2-Methoxy-2-Oxo-1,2-Oxaphospholan-3-Ols

Abstract

Conformational behaviour of about 30 2-methoxy-2-oxo-1,2- oxaphospho l an-3-0 1 s containing various substituents was examined by ¹H and ¹³C NMR. Vicinal coupling constants J(HCCH), J(HCCP), J(HCOP), J(CCOP) and J(CCCP) were employed in this study. Conformation of the 1,2-oxaphospholane ring is governed almost exclusively by substituents at C-3, C-4 and C-5, as we l l as by their orientation. The configuration of the P atom has little or no influence on conformation of the ring in diastsreomeric pairs. Strong preference of phenyl, methyl and substituted methyl groups to occupy the equatorial or pseudoequatoria l positions was observed for all but one compounds studied. In the cis-fused bicyclic syst ems conformat ionally rigid 6-membered rings forced the 1,2-oxaphospholane rings to adopt an enve l ope-l ike (E₄) conformation. No influence of the p=o……HO-C-3 hydrogen bond on conformation of the 1,2-oxaphospholane ring was found. Preferred conformations for (2R, 3R, 4R)-3-(hydroxymethyI)-2-methoxy-2-oxo-1,2-oxaphospho lane-3,4-diol and its triacetate are shown below.     

Analyse Conformationnelle par RMN du Proton des Oxo-2 Oxathiazannes-1,2,3 (Sulfinamates Cycliques) Diversement Substitués en 3, 4 et 6

In this study, carried out with 16 compounds, the chair form with an axial S?O group (CA) is found, in the absence of C-4, C-5 and C-6 substituents, to be the most stable (ΔG>8,4 kJ mole^?1), as previously reported for analogous cyclic sulfites. When methyl or tert-butyl substituents are present on the 4 and 6 carbon atoms, the conformation of the ring depends on their respective orientation towards the S?O group, and on the nature of the substituent of the nitrogen atom. For the trans isomers, the conformation remains anancomeric chair (CA) except when important gauche interactions exist: thus the strong Me/tBu gauche interaction in the 3-tert-butyl-4-t-methyl-2-r-oxo-1,2,3-oxathiazan induces a twist form with a 3,6-axis and an axial S?O group (CNA). When the 4- or 6-substituent is cis, the conformation of the sulfinamate may be either a chair form with an axial S?O group (CA), if the 4-substituent is a methyl, (even with a tert-butyl group in the 3-position which would be in the axial orientation) or a twist form with a 1,4-axis and an axial S?O group (COA) if the 4-substituent is a tert-butyl. Unlike cyclic sulfites, the equatorial SO chair form (CE) and the twist forms with a 2,3-axis and an isoclinal S?O group (CS, CS′) are rarely involved.     

Neutron Diffraction Study of [Nd(AlMe4)3]⋅0.5 Al2Me6 at 100 K: The First Detailed Look at a Bridging Methyl Group with a Trigonal-Bipyramidal Carbon Atom

Weak agostic Nd⋅⋅⋅H interactions and Nd−C bonds are involved in the bonding of the bridging methyl groups in the title compound (see sketch on the right): Two of the three H atoms of the methyl group are directed at the Nd center. The C atoms have distorted trigonal-bipyramidal geometry with the Nd atom and one of the H atoms (H_A) as axial ligands, and the Al atom and the other two H atoms (H_B and H_C) in equatorial positions. The Al₂Me₆ “solvate” molecule is disordered.     

trans‐Bis(diethanolamine‐N,O)bis(saccharinato‐N)cadmium(II)

The structure of the title complex consists of isolated [Cd(C₇H₄NO₃S)₂(C₄H₁₁NO₂)₂] units. The Cd²⁺ cation lies on an inversion centre and is octahedrally coordinated by two N,O‐bidentate diethanol­amine (dea) and two N‐bonded saccharinate (sac) ligands [saccharin is 1,2‐benziso­thia­zol‐3(2H)‐one 1,1‐dioxide]. The dea ligands constitute the equatorial plane of the octahedron, forming two five‐membered chelate rings around the Cd^II ion, while the sac ligands are localized at the axial positions. The Cd—N_sac, Cd—N_dea and Cd—O_dea bond distances are 2.3879 (12), 2.3544 (14) and 2.3702 (13) Å, respectively. The H atoms of the free and coordinated hydroxyl groups of the dea ligands are involved in hydrogen bonding with the carbonyl and sulfonyl O atoms of the neighbouring sac ions, while the amine H atom forms a hydrogen bond with the free hydroxyl O atom. The individual mol­ecules are held together by strong hydrogen bonds, forming an infinite three‐dimensional network.     

Transition metal complexes with thio­semicarbazide-based ligands. XLII.

In the title compound, [Ni(C₂H₇N₃S)₂(C₃H₄N₂)₂]I₂, the Ni^II ion assumes a centrosymmetric distorted octahedral geometry. The two mol­ecules of S-methyl­iso­thio­semicarbazide are coordinated as bidentate ligands via the terminal N atoms, forming five-membered chelate rings. The I atoms are approximately in the equatorial plane of the chelate rings at a similar distance from both. The five-membered chelate rings are almost planar and exhibit flattened envelope conformations. There is a weak intermolecular interaction between the lone pair of electrons of the S atom and the center of the pyrazole ring.     

AN ALKOXO-BRIDGED BINUCLEAR MANGANESE COMPLEX BIS(μ-PROPIONATO-O: O′)-BIS(μ-3-SALICYLIDENE-AMINO-PROPANOLATO-O″,O‴,N:O″) BISMANGANESE(III)

Abstract

The alkoxo-bridged binuclear complex of Mn^III, [Mn₂(salpa)₂(C₂H₅—COO)₂] (H₂salpa = 3-salicylidene-amino-1-propanol), has been prepared and its crystal structure has been determined by X-ray diffraction. The structure of the title complex consists of discrete binuclear manganese units in which the Mn^III atoms are bridged by two alkoxo ligands via oxygen atoms and supported by two carboxylato bridging ligands in the syn - syn fashion. The complex lies about a crystallographic inversion center. Each Mn^III atom is located in an elongated octahedral environment with one imino N, one phenolic O and two alkoxo O atoms coordinated in the equatorial plane and two O atoms from carboxylato groups at the apical positions. The remarkably longer coordination bond distances in the axial direction are attributed to Jahn-Teller distortion at the d ⁴ manganese center. The distance between the manganese atoms is 2.8662(9) Å. The asymmetrical and symmetric stretching vibrations for carboxylato groups found at 1550 and 1440 cm^?1, respectively, with a separation of less than 200 cm^?1 confirmed the bidentate mode of the carboxylato groups.