Fluorsulfonylmethylidene sulfur difluoride oxide,FSO2?CH  SF2  O

SO₃ adds across the CS double bond of H₂C  SF₄ with formation of 2-tetrafluoro-4-dioxo-1,2,4-oxadithietane, which rearranges to fluorsulfonylmethylidene sulfur difluoride oxide, F SO₂ CH  SF₂  O in the presence of CsF. © John Wiley & Sons, Inc.     

Xanthates as Chain‐Transfer Agents in Controlled Radical Polymerization (MADIX): Structural Effect of the O‐Alkyl Group

The capability of three chain‐transfer agents, O‐alkyl‐S‐(1‐ethoxycarbonyl)ethyl xanthates (CH₃CHCO₂C₂H₅)S(CS)OZ′, to control the free‐radical polymerization of styrene and ethyl acrylate by the MADIX process was examined. The reactivity of the xanthates varied according to the following trend: Z′  CH₂CH₃ < CH₂CF₃ < CH[P(O)(OEt)₂]CF₃. This change in reactivity allowed a lowering of the polydispersity index from 2.0 for Z′  CH₂CH₃ to 1.15 for Z′  CH[P(O)(OEt)₂]CF₃ in the case of the polymerization of styrene.

Evolution of M _w/M _n with conversion during the polymerization of ethyl acrylate in the presence of xanthates X₁ , X₂ and X₃ . Reaction conditions: [EA]₀ = 4.6 M , [X]₀ = 5.75 × 10⁻² M , [AIBN]₀ = 1.72 × 10⁻³ M ; T = 80 °C ; solvent: toluene.     

Methylcobaltverbindungen mit nicht chelatisierenden Liganden,IV. Monoolefinkomplexe

Methylcobalt Compounds with Non-chelating Ligands, IV. Monoolefin Complexes Tris(trimethylphosphane)cobalt(I) halides in ether solvents saturated with olefin at low temperatures from monoolefin complexes which are prone to dissociation. Upon reaction with methyl-or phenyllithium more stable compounds are formed of the composition CoR(CC)L₃ ( 1 – 4 ) (R  CH₃; CC  C₂H₄, C₃H₆, cyclo-C₅H₈; R  C₆H₅; CC  C₂H₄; L  P(CH₃)₃). In solution the fluctional molecules adopt a ground state structure containing a σ-bonded group and an olefin ligand in adjacent positions (trigonal-bipyramidal: CH₃ axial and C₂H₄ equatorial or C₆H₅ and C₂H₄ equatorial). The latter arrangement is confirmed for the crystalline state by an X-ray structure determination of (ethene)phenyltris(trimethylphosphane)cobalt ( 4 ). An equatorial plane of coordination along a Co P bond not only contains both ethene-C atoms but also all the atoms of the phenyl group. The compound is thermally decomposed to give biphenyl and (ethene)tris-(trimethylphosphane)cobalt(0). No products of an olefin insertion reaction are observed.     

Nitrene Insertion into C?C and C?H Bonds of Diamide Diimine Ligands Ligated to Chromium and Iron

The impact of redox non‐innocence (RNI) on chemical reactivity is a forefront theme in coordination chemistry. A diamide diimine ligand, [{‐CHN(1,2‐C₆H₄)NH(2,6‐iPr₂C₆H₃)}₂]ⁿ (n=0 to −4), (dadi)ⁿ, chelates Cr and Fe to give [(dadi)M] ([ 1 Cr(thf)] and [ 1 Fe]). Calculations show [ 1 Cr(thf)] (and [ 1 Cr]) to have a d⁴ Cr configuration antiferromagnetically coupled to (dadi)²⁻*, and [ 1 Fe] to be S=2. Treatment with RN₃ provides products where RN is formally inserted into the C C bond of the diimine or into a C H bond of the diimine. Calculations on the process support a mechanism in which a transient imide (imidyl) aziridinates the diimine, which subsequently ring opens.     

Adsorption of small molecules on helical gold nanorods: A relativistic density functional study

We study the adsorption of a variety of small molecules on helical gold nanorods using relativistic density functional theory. We focus on Au₄₀ which consists of a central linear strand of five gold atoms with seven helical strands of five gold atoms on a coaxial tube. All molecules preferentially adsorb at a single low‐coordinated gold atom on the coaxial tube at an end of Au₄₀. In most cases, there is significant charge transfer (CT) between Au₄₀ and the adsorbate, for CO and NO₂, there is CT from the Au₄₀ to adsorbate while for all other molecules there is CT from the adsorbate to Au₄₀. Thus, Au₄₀‐adsorbate can be described as a donor–accepter complex and we use charge decomposition analysis to better understand the adsorption process. We determine the adsorption energy order to be C₅H₅N >NO₂ > CO > NH₃ > CH₂?CH₂ > CH₂?CH? CHO > NO > HC?CH > H₂S > SO₂ > HCN > CH₃OH > H₂C?O > O₂ > H₂O > CH₄ > N₂. We find that the Au? C, Au? N, Au? S, and Au? O bonds are surprisingly strong, with clear implications for reactivity enhancement of the adsorbate. The Au? H bond is relatively weak but, for interactions via an H atom that is bonded to a carbon atom (e.g., CH₄), we find that there is large charge polarization of the Au? H? C moiety and partial activation of the inert C? H bond. Although the Au? S and Au? O bonds are generally weaker than the Au? C and Au? N bonds, we find that adsorption of H₂S or H₂O causes greater distortion of Au₄₀ in the binding region. However, the degree of distortion is small and the helical structure is retained, demonstrating the stability of the helical Au₄₀ nanorod under perturbations. © 2014 Wiley Periodicals, Inc.     

Stereoselective Introduction of Steroid Side Chains at C (17) and C (20)

A simple and efficient new method for the highly stereoselective (at C (17) and C (20)) introduction of steroid side chains which are suitably functionalized for further elaboration is presented. The ene reaction of (17 Z)-ethylidene steroids, which are readily obtained from 17-keto steroids via a Wittig reaction, with various enophiles such as formaldehyde and acrylate esters leads to useful intermediates which contain the natural steroid configuration at C (20). Catalytic hydrogenation of the Δ¹⁶-double bond occurs from the α-face to stereospecifically generate the correct configuration at C (17). An additional chiral center at C (23) is also introduced stereoselectively by the use of methyl 2-chloroacrylate as the enophile.     

The tautomerization and ring closure in the Claisen rearrangement: A DFT study

Elementary processes of the aromatic Claisen rearrangement were investigated by DFT calculations. First, rearrangements of four substrates Ph—O—CH₂—CHCH₂ [A], Ph—O—CH₂—CHCH(OMe) [B], Ph—O—CH₂—CHCH₂····BF₃ [C], and Ph—O—CH—CHCH(OMe)····BF₃ [D] were examined. In these systems, the tautomerization is initiated by the intermolecular proton transfer involving the transient ion‐pair intermediate. An ignition‐propagation chain‐reaction mechanism in the tautomerization was suggested. For [A], the (ortho‐allyl phenol → α‐methyl‐dihydrobenzofuran (α‐methyl‐cumarane)) process was found to be ready and the product of the Claisen rearrangement seems to be the cumarane rather than the phenol. In [D] (activated both by the terminal methoxy group and by the BF₃ catalyst), not the [3,3]‐sigmatropic shift but the tautomerization is the rate determining step. Second, the parent system, Ph—O—CH₂—CHCH₂, was investigated with (H₂O) _n (n = 2, 4, 6, and 10) systematically. The tautomerization takes place by the proton transfer via the water dimer or trimer. Except n = 2, similar changes of Gibbs free energies were obtained from the ether substrate to the cumarane.     

2-Cyanoacrylates as reagents in heteroatomic synthesis (a review)

Several types of addition reactions to the CC bond of alkyl 2-cyanoacrylates, CH₂C(CN)COOR ( 1 ), are considered. The first examples deal with addition of CH-Acids (p K _a less than 13) and of H₂S in the presence of catalytic amounts of strong amines, also of mercaptans, thiocarboxylic, and thiophosphoric acids. P-Sulfenylchlorides and acidic phosphites add irreversibly at 20°C to form addition products in accordance with the distribution of charges in 1 . HCl reversibly adds to 1 and to the acid chloride CH₂C(CN)COCl ( 2 ). Alcohols and H₂O also add reversibly to the acid CH₂C(CN)COOH ( 3 ) and to esters of 1 to transform 1 and 3 into polymers. Triethylsilane in the presence of CF₃COOH ( 4 ) reduces the CC bond of 1 and 3 to the corresponding saturated derivatives. The second set of examples involves reactions of 1 with P-III compounds in the presence or absence of 4 . Ph₃P as well as other weak nucleophiles reversibly add to 1 in the absence of 4 to cause instant polymerization. However, 4 protonates an initially formed zwitter-ion in the reaction of 1 with Ph₃P,(EtO)₂PCl,Ph₂PCl and thiourea to afford stable addition products. IR spectroscopy reveals the formation of H-complexes of 4 with the CN and COOR groups of 1 , which stimulates the addition of the weak nucleophile (o-C₆H₄O₂)PCl to the CC bond of 1 . This reagent does not react with 1 in the absence of 4 . Strong nucleophiles, Alk₃P, and (Et₂N)₃P in excess irreversibly add at 20°C to 1 to form zwitterions, which specifically react with PhNCO to give stable products. 1,3,2-Dioxaphospholes react with 1 either to form spirophosphoranes or 2-cyano-3-phosphoranylpropionates.     

UV Laser‐Induced Gas‐Phase Copolymerization of Carbon Disulfide and Ethene

Summary: The laser irradiation at 193 nm of a gaseous mixture of carbon disulfide and ethene induces the copolymerization of both compounds and affords the chemical vapour deposition of a C/S/H polymer, the composition of which indicates the reaction between two to three CS₂ molecules and one C₂H₄ molecule. Polymer structure is interpreted on the basis of X‐ray photoelectron and FT‐IR spectra as consisting of >CS, >CC<,  CH₂ CH₂ , (CC)S_nC_{4 − n},  C (CS) S ,  S (CS) S , and C S S C configurations. The gas‐phase copolymerization of carbon disulfide and ethene represents the first example of such a reaction between carbon disulfide and a common monomer.

Scheme showing the expected reaction of excited CS₂ molecules with other CS₂ molecules to form dimers, which then react with another CS₂ molecule or add to ethene.     

Synthesis of Chain‐End Functionalized Polyolefins with a Bis(phenoxy imine) Titanium Catalyst

Polyethylenes and highly syndiotactic poly(propylene)s possessing chain end hydroxyl groups were synthesized by living polymerizations using L₂TiCl₂ [ 1 , L: C₆F₅NCH(2 O C₆H₃ 3 ^tBu)]/MAO and functionalized α‐olefins, H₂CCH(CH₂)_n Y [ 2 ; YOAlMe₂, n = 4 ( 2a ); YOSiMe₃, n = 9 ( 2b )]. Because the primary insertion of 2 to a cationic species L₂Ti⁺ Me ( 3 ) derived from 1 /MAO is much faster than the successive secondary insertion of 2 , addition of an equimolar amount of 2 to 3 resulted in the quantitative formation of L₂Ti⁺ CH₂ CH(Me) (CH₂)_n Y [ 4 ; YOAlMe₂, n = 4 ( 4a ); YOSiMe₃, n = 9 ( 4b )]. These cationic species 4 served as functionalized initiators for the living polymerization of both ethylene and propylene and afforded polyolefins having extremely narrow molecular weight distributions and a hydroxyl group at the initiating chain end. The terminating chain end of the syndiotactic poly(propylene)s was also functionalized by adding an excess amount of 2b as a chain end capping agent to the living L₂Ti–polymeryl species. Due to much slower insertion of the second molecule of 2b relative to the first one, the obtained polymers were end capped quantitatively by a single molecule of 2b . Telechelic syndiotactic poly(propylene)s were successfully synthesized through a living polymerization initiated by 4b and an end capping using 2b .

     

Hydrogenation of Styrene‐Butadiene Rubber Catalyzed by Ru(CHCHPh)Cl(CO)(PCy3)2

Summary: The hydrogenation of a copolymer of styrene and butadiene (SBR) catalyzed by Ru(CHCHPh)Cl(CO)(PCy₃)₂ was experimentally investigated within the temperature range of 120–160 °C, at Pequation/tex2gif-inf-7.gif of 300–1 200 psi, and a catalyst concentration of 10–78 × 10⁻⁶ M . Special attention was paid to minimizing the catalyst metal residue and crosslinking in the product. The results indicated that high‐quality hydrogenated SBR was achieved without crosslinking and the metal residue was less than 7 ppm without a post‐treatment.

IR spectra of the styrene–butadiene rubber before (a) and after (b) hydrogenation with the Ru(CHCHPh)Cl(CO)(PCy₃)₂ catalyst were observed as reported here. The disappearance of all characteristic absorbencies of CC (724, 910, 967, and 994 cm⁻¹) suggests nearly quantitative hydrogenation of the CC bonds.     

1H-NMR-Spektroskopische Untersuchungen an isomeren Alkendiinen

¹H NMR spectra of several aliphatic and phenyl substituted alkenediynes have been obtained. Chemical shifts and coupling constants of these compounds are discussed in conjunction with some compounds described in the literature. Chemical shifts of the protons from isomeric alkenediynes R? C?C? C?C? CH?CH₂, R? CH?CH? C?C? C?CH and R? CH?CH? C?C? C?C? CH₃ (R = H, alkyl, C₆H₅, C₆H₄OCH₃-p) are well correlated with cis/trans-isomerism and electronic effects of substituents at the C?C bond. The coupling constants were found to be only slightly dependent on the substitution at the double bond. We could resolve couplings over a maximum of eight bonds in the alkenediyne system.     

Herstellung von Iminen durch Gasphasen-Pyrolyse: N-Methyl-äthylidenimin

N-methyl-ethylidenimine (CH₃ CHN CH₃) was obtained by pyrolysis of 2-methylaziridine in a gas phase flow system, using quartz as a catalyst. Pyrolysis of aziridine gave mainly N-methyl-methylenimine (CH₂N CH₃). Under the conditions used in this work, pyrolysis of both compounds surprisingly showed cleavage of the CC-bond in the three-membered ring. No monomeric ethylidenimine (CH₃ CHNH) could be isolated by pyrolysis of trimeric ethylidenimine (2,4,6-trimethyl-hexahydro-1,3,5-triazine), whereas N-vinyl-ethylidenimine (CH₃ CHN CHCH₂) could be identified as one of the pyrolysis products. NMR. data for N-methyl-ethylidenimine and N-vinyl-ethylidenimine are given for identification purposes.     

Heterobimetallic heterocyclic derivatives of indium(III)

Reactions of InCl₃ with potassium salts of bifunctional tridentate (L¹H₂HOC₆H₄CH NCH₂CHMeOH) and monofunctional bidentate (L²HHOC₆H₄CHN-i-Bu) Schiff bases in 1:1 and 1:2 molar ratio in benzene afford complexes In(L¹)Cl and In(L²)₂Cl, respectively. On reaction with potassium isopropoxymetallates KB(O-i-Pr)₄, KAl(O-i-Pr)₄, KTi(O-i-Pr)₅, and KNb(O-i-Pr)₆, they produce interes- ting heterobimetallic heterocyclic complexes. These are characterized by elemental (N, B, Al, Ti, and Nb) analyses, molecular weight measurements, and spectral [IR, NMR (¹H, ¹³C, ¹¹B, and ²⁷Al)] studies. Probable structures are suggested for them. © 2003 Wiley Periodicals, Inc. 15:21–25, 2004; Published online in Wiley InterScience (www.interscience.wiley.com). DOI 10.1002/.hc10206     

Geminal bond participation in Alder ene reaction

We applied the geminal bond participation theory to Alder ene reactions. The interaction between the σ-orbital at the Z-position of the double bond of propene and the π^∗-orbital of ethylene was predicted to be bonding, while that at the E-position should be antibonding. This prediction was confirmed by the bond model analysis of the model compound. These results suggest that the reactivity could be enhanced by substituting a more electron-donating σ-bond at the Z-position. To examine our prediction, theoretical calculations were performed for the systematically substituted substrates. The prediction was confirmed except in the case where the inductive effect of oxygen could affect the reactivity. The same trend in reactivity was observed for formaldehyde as an enophile.     

Elementorganische Amin/Imin-Verbindungen,XXXI. Cyclometallierung bei N-tert-Butyl-Phosphor-Stickstoff-Iridiumkomplexen

Element-Organic Amine/Imine Compounds, XXXI. - Cyclometallation with N-tert-Butyl-Phosphorus-Nitrogen Iridium Complexes The interaction of R¹R²N–PNR³ ( 1 ) (R¹  SiMe₃, tBu, iC₃H₇; R²  R³  SiMe₃, tBu) with [M(COD)(μ-Cl)]₂ ( 2 ), M  Rh, Ir, affords the amino(imino)phosphane complexes 3 , whose PN bond adds methanol with formation of the diamidophosphite complexes 4 . Already below 0°C the iridium compounds of 4 undergo cyclometallation of a tBu methyl group (R²) with formation of the hydrido-iridium metallaheterocycles 5 . The structures of 4b and 5a are elucidated by X-ray analyses.     

Ab initio studies on reaction H2C=C(OH)Li+CH3 + (CH3 -)

The possible structures and isomerizations of H₂C=C(OH)Li are studied theoretically by the gradient analytical method at RHF/6-31+G level. According to these results, reactions of H₂C=C(OH)Li with CH₃ ⁺ and CH ₃ ^- are investigated thoroughly. When H₂C=C(OH)Li reacts with CH ₃ ⁺ , H_zC=C(OH)Li firstly changes from structure1 to structure4, and then combines with CH₃ ⁺. In this reaction, the configuration of central carbon is retained. When H₂C=C(OH)Li reacts with CH ₃ ^- , structure1 firstly breaks its C-O bond to give contact ion-pair. Then through transition state16 which is similar to structure2, the attack of CH ₃ ^- from the opposite side of^-OH replaces^-OH group and inverts the configuration of carbenoid carbon atom. All the results show that the ambident reactivity of carbenoid has close relationship with the stability of special structures. Project supported by the National Natural Science Foundation of China (Grant No. 29773025).     

Dreizentren-oxidative Addition von Phosphor-Yliden an Ru3(CO)12

Three-Centre Oxidative Addition of Phosphorus Ylides to Ru₃(CO)₁₂ Phosphorus ylides undergo oxidative addition to Ru₃(CO)₁₂ to yield a wide range of Ru₃ clusters with triply bridging organic ligands derived from the ylides. Ph₃PCH₂ forms HRu₃(CO)₉(μ₃1-Ph₃P — CH — CO) ( 1 ) containing a phosphonio enolate. Ph₃PCH — CHO yields a product mixture containing the phosphonio enolate-bridged cluster and its PPh₃ derivative 6 , the phosphoniomethylidyne-bridged compound H₂Ru₃(CO)₉(μ₃1-C — PPh₃) ( 5 ), and the ketenylidene-bridged compound H₂Ru₃(CO)₈(PPh₃)(μ₃1-C — CO) ( 7 ). Thermal treatment converts the phosphonio enolate ligand (in 1 ) into the phosphoniomethylidyne ligand (in 5 ), and the latter into the ketenylidene ligand (in 7 ). With Ph₃PCH — C(O)Me and Ru₃(CO)₁₂ ortho1-metalated Ru₃ derivatives 10, 11 of the phosphonio ketone R₃P — C — C(O)Me are produced, and likewise with Ph₃PCH — COOEt the ortho1-metalated derivative 12 of the phosphonio ester R₃P — C — CO₂Et. Me₃PCH — COOtBu is oxidatively added to form HRu₃(CO)₉(μ₃1-Me₃P — C — COOtBu) ( 13 ) bearing a phosphonio ester ligand. — The crystal structures of 6 and 13 are reported. The sequence of Ru₃ clusters and the bonding modes of the μ₃ ligands can be related to the surface reactions during Fischer-Tropsch catalysis.     

C?H Activation of Benzene by a Photoactivated NiII(azide): Formation of a Transient Nickel Nitrido Complex

Photochemical activation of nickel‐azido complex 2 [Ni(N₃)(PNP)] (PN^HP=2,2′‐di(isopropylphosphino)‐4,4′‐ditolylamine) in neat benzene produces diamagnetic complex 3 [Ni(Ph)(PN^PN^H)], which is crystallographically characterized. DFT calculations support photoinitiated N₂‐loss of the azido complex to generate a rare, transient Ni^IV nitrido species, which bears significant nitridyl radical character. Subsequent trapping of this nitrido through insertion into the Ni P bond generates a coordinatively unsaturated Ni^II imidophosphorane PN donor. This species shows unprecedented reactivity toward 1,2‐addition of a C H bond of benzene to form 3 . The structurally characterized chlorido complex 4 [Ni(Cl)(PN^PN^H)] is generated by reaction of 3 with HCl or by direct photolysis of 2 in chlorobenzene. This is the first report of aromatic C H bond activation by a trapped transient nitrido species of a late transition metal.