Highly Enantioselective Catalytic Hetero-Diels–Alder Reaction with Inverse Electron Demand

Valuable substrates for the synthesis of natural products , compounds 3 (R¹=alkyl, aryl, alkoxy; R², R³=alkyl) are formed from β,γ-unsaturated α-keto esters 1 and vinyl ethers 2 by the title reaction [Eq. (1)]. Copper(II ) bisoxazolines act as catalysts, and in many cases enantiomeric excesses higher than 99.5 % are achieved.     

New one-pot, efficient, and regioselective method for the synthesis of 3-Trifluoromethyl-1H-1-phenylpyrazoles and alkyl 3-carboxylate analogs

An efficient and regioselective procedure for the synthesis of a series of alkyl(aryl/heteroaryl) substituted 3-trifluoromethyl-1H-1-phenylpyrazoles and alkyl 3-carboxylate analogs, from the cyclocondensation reactions of 4-alkoxy-1,1,1-trihaloalk-3-en-2-ones [CX₃C(O)CR²=CR¹(OMe/OEt), where R¹ = H, Me, Ph, 2-Furyl; R² = H; R¹-R² = -C₄H₈- and X = F, Cl] and 1-phenylsemicarbazide in an acidified alcoholic medium (R³OH/H₂SO₄), where R³ = Me, Et, Prⁱ was successfully applied and is described here in detail.     

Studies in negative ion mass spectrometry. VII—Negative ion mass spectra of copper (II) β-diketonate complexes

Electron capture processes in a series of copper (II) β-diketonate complexes of formula Cu[R¹COCHCOR²]₂ (where R¹ is an alkyl, perfluoroalkyl or aryl group and R² either an alkyl or aryl group) have been examined. Molecular anions, ligand ions and some novel rearrangement ions have been observed with these compounds. Relative intensities of fragment ions were dependent on the substituents R¹, R² as well as the electron energy and compound pressure in the ion source. By operating the mass spectrometer at compound pressures of c. 4×10^?6 Torr and higher, reproducible negative ion mass spectra (free from any significant ion-molecule contributions) have been obtained for all compounds of the series.     

Polarity and Conformatios of Phosphorylethylenes and Phosphorylacetates in Solution

Abstract

A series of derivatives R¹R²P(X)R³, where R¹=R²=Ph. R³= -CH=CH-Me, X=O(I); R¹=Me, R²=Ph, R³= -CH=CH₂, X=O(II); R¹=R²=Ph, R³= -CH=CH₂, X=Se(III) and R¹R²P(O)-CH₂C(O)OX, where R¹=Ph, R²= -CH=CH₂, X=Ment?(IV); R¹=Ph-2-OMe, R²=Ph, X=Ment?(V); R¹=R²=CH₂Ph, X=Et(I), were investigated by means of dipole moments method. The problem of conjugation in phosphorylethylenes and conformation behaviour of phosphorylacetates was considered. DM (exp.) of (I-IV), determined in CC1₄ solution are 4.48(I), 4.27(II), 4.97(III), 4.21(IV), 5.21(V) and 4.02 D (VI). The intramolecular electronic interactions of phosphoryl group with unsaturated fragment did not displays in polarity properties of compounds (I-III). The experimental dipole moments of derivatives (I-III) are equal to the calculated values of DM. DM (IV-VI) is very sensitive to orientation of the P=O and C=O polar bonds. Because DM (exp.) of these compounds very sensitive to its orientation. DM (calc.) for cis- and trans- orientation of P=O and C=O dipoles are really different, that allows to drow the conclution that, in the contrast to the crystal state, the corresponded dipoles prefer an anti array in solution.     

1,2-dihydro-1,2,4,3-triazaphospholo[4,5-a]quinolines as electron carriers in the electrochemical reduction of 1,1-dichloro-2-methoxycarbonyl-2-methylcyclopropane

Electrochemical reduction of 1-X-1-R¹-5-methyl-2-phenyl-7-R²-1,2-dihydro-1,2,4,3-tri-azaphospholo[4,5-a]quinolines1–5 (1: X is the lone electron pair (LEP), R¹=Et₂N, R²=Me;2: X=LEP, R¹=Ph, R²=H;3: X=S, R¹=Et₂N, R²=H;4: X=LEP, R¹=Et₂N, R²=H;5: X=LEP, R¹=MeO, R²=H) in DMF with 0.1M Bu₄NI as supporting electrolyte is reversible and results in metastable radical anions. Radical anions of compounds1–3 efficiently reduce 1,2-dichloro-2-methoxycarbonyl-2-methylcyclopropane both in the presence and in absence of Ni¹¹ ions. Effective reduction rate constants have been evaluated. Translated fromIzvestiya Akademii Nauk. Seriya Khimicheskaya, No. 11, pp. 2088–2091, November, 1999.     

Effects of methyl substituents on the proton chemical shifts in the NMR spectra of the twenty methyl and ethyl substituted hydrazines. Electronegativity values for hydrazyl groups

The C? H proton NMR spectra of the twenty conceivable methyl and ethyl substituted hydrazines are presented and analyzed with respect to effects on chemical shifts of the C? H protons caused by replacement of hydrogen by methyl and ethyl groups on the C? N? N? C chain. Thirteen different methyl substituent effects and six different ethyl substituent effects are identified and evaluated. Most of the effects are shielding and in accordance with an electron-releasing inductive effect of alkyl groups. A deshielding effect (the ‘C? C bond effect’) is observed when a methyl group replaces the hydrogen on the carbon bearing the hydrogen in focus and primary hydrogen on the carbon bearing the hydrogen in focus and primary hydrogens become secondary, as observed in other systems. On the basis of their effects on the chemical shifts of methyl protons in CH₃X, eighteen different hydrazyl groups (× = ? NR₁NR₂R₃) fall into three classes: I (R₁ = H; R₂, R₃ = H or alkyl); II (R₁ = alkyl; R₂ and/or R₃ = H); III (R₁, R₂ and R₃ = alkyl), with slightly different electronegativities: 2·94, 2·83 and 2·74, respectively.     

Heavy Carbene Analogues: Donor‐Free Bismuthenium and Stibenium Ions

Kinetically stabilized congeners of carbenes, R₂C, possessing six valence electrons (four bonding electrons and two non‐bonding electrons) have been restricted to Group 14 elements, R₂E (E=Si, Ge, Sn, Pb; R=alkyl or aryl) whereas isoelectronic Group 15 cations, divalent species of type [R₂E]⁺ (E=P, As, Sb, Bi; R=alkyl or aryl), were unknown. Herein, we report the first two examples, namely the bismuthenium ion [(2,6‐Mes₂C₆H₃)₂Bi][BAr^F₄] ( 1 ; Mes=2,4,6‐Me₃C₆H₂, Ar^F=3,5‐(CF₃)₂C₆H₃) and the stibenium ion [(2,6‐Mes₂C₆H₃)₂Sb][B(C₆F₅)₄] ( 2 ), which were obtained by using a combination of bulky meta‐terphenyl substituents and weakly coordinating anions.     

An NHC-Stabilized H2GeBH2 Precursor for the Preparation of Cationic Group 13/14/15 Hydride Chains

The synthesis, characterization and reactivity studies of the NHC-stabilized complex IDipp ⋅ GeH₂BH₂OTf ( 1 ) (IDipp=1,3-bis(2,6-diisopropylphenyl)imidazolin-2-ylidene) are reported. Nucleophilic substitution of the triflate (OTf) group in 1 by phosphine or arsine donors provides access to the cationic group 13/14/15 chains [IDipp ⋅ GeH₂BH₂ERR¹R²]⁺ ( 2 E=P; R, R¹=H; R²=^tBu; 3 E=P; R=H; R¹, R²=Ph; 4 a E=P; R, R¹, R²=Ph; 4 b E=As; R, R¹, R²=Ph). These novel cationic chains were characterized by X-ray crystallography, NMR spectroscopy and mass spectrometry. Moreover, the formation of the parent complexes [IDipp ⋅ GeH₂BH₂PH₃][OTf] ( 5 ) and [IDipp ⋅ GeH₃][OTf] ( 6 ) were achieved by reaction of 1 with PH₃. Accompanying DFT computations give insight into the stability of the formed chains with respect to their decomposition.     

四个基于间苯二(取代水杨醛酰腙)的有机锡配合物的溶剂热合成、结构和荧光性能

采用间苯二（取代水杨醛酰腙）（H₄L）与R₃²SnOH溶剂热反应,或间苯二甲酰肼、3-叔丁基水杨醛和三环己基氢氧化锡一锅溶剂热法反应,合成了4个新的有机锡配合物（SnR²）₂L（1~4）,其中,H₄L=m-Ph（CONH—N=CH（o-OH） PhR¹）₂;R¹=NEt₂,R²=Ph（1）;R¹=3,5-di-tert-butyl=3,5-t-2Bu,R²=Ph（2）;R¹=3,5-t-2Bu,R²=Cy（3）;R¹=3-tert-butyl=3-t-Bu,R²=Cy（4）。经元素分析、红外光谱和（¹H、¹³C、¹¹9Sn）核磁共振谱表征,并用X射线衍射方法确证配合物1~4的结构。配体H₄L的2个取代水杨醛酰腙链向内取向并与锡原子配位形成3个内向E型配合物1~3,取代水杨醛酰腙链向外取向并与锡原子配位形成外向E型配合物4。配合物1、2和4属于三斜晶系P1空间群,配合物3属于单斜晶系P2₁/c空间群。中心锡与配位原子构成畸形双角三锥构型。配体、配合物-三氯甲烷溶液的荧光性能表明,当具有弱荧光的配体m-Ph（CONH—N=CH（o-OH） PhNEt₂）₂（H₄L¹）和无荧光的配体m-Ph（CONH—N=CH（o-OH） Ph（3,5-t-2Bu））₂（H₄L²）分别与苯基锡、环己基锡配位后,配合物-三氯甲烷溶液发出强荧光。     

Ein einfacher Weg zu α-substituierten (E)-3-Oxo-1-alkenylphosphonsäureestern

Zusammenfassung -Substituierte -Acylvinylphosphonate3 mitE-Konfiguration [R ²CO-CH=C(R ¹)-P(O)(OR)₂], werden in guten Ausbeuten durchWittig-Reaktion von Acylphosphonsäureestern1 [R ¹CO-P(O)(OR)₂,R ¹=Alkyl oder Aryl] mit (2-Oxoalkyliden)triphenylphosphoranen2 [R ²CO-CH=PPh ₃,R ²=Alkyl, O-Alkyl oder CH₂ X (X=Br, OMe, CO₂ Et)] erhalten.

---

A convenient route to -substituted dialkyl (E)-3-oxo-1-alkenylphosphonates

-Substituted dialkyl (E)--acylvinylphosphonates [R ²CO-CH=C(R ¹)-P(O)(OR)₂,3], are easily obtained in good yields byWittig-reaction of dialkyl acylphosphonates1 [R ¹CO-P(O)(OR)₂,R ¹=alkyl or aryl) with 2-oxoalkylidene triphenylphosphoranes2 [R ²CO-CH=PPh ₃,R ²=alkyl, O-alkyl and CH₂ X (X=Br, OMe, CO₂ Et)].

     

Nickel‐Catalyzed Borylative Coupling of Alkynes,Enones, and Bis(pinacolato)diboron as a Route to Substituted Alkenyl Boronates

Three‐component coupling reactions of an alkyne, an enone, and a diboron reagent provide access to highly substituted alkenyl boronates in good to excellent yields (see scheme). The coupling is highly regio‐ and stereoselective, and the products are amenable to further functional‐group transformations. R¹,R²=H, alkyl, aryl, CO₂Me; R³=alkyl, Ph; R⁴,R⁵=H, alkyl.

     

Addition–Hydroamination Reactions of Propargyl Cyanamides: Rapid Access to Highly Substituted 2‐Aminoimidazoles

A valuable pharmacophore , the 2‐aminoimidazole moiety, can be accessed with a variety of substitution patterns through an addition–hydroamination–isomerization sequence (see scheme; R¹,R⁴,R⁵=alkyl; R³=alkyl, aryl; R²=H, alkyl, aryl). The synthesis of the propargyl cyanamide precursors through a three‐component coupling enables the preparation of this important heterocyclic core structure in just three steps.

     

Mössbauer Studies on Spin State of the Thermal Decomposition of Substituted Tris (2-Pyridylimine) Iron (II) Thiocyanate

The spin states of iron (II) in FeL₂(NCS)₂ produced from the thermal decomposition of FeL₈(NCS)₂ (L=2-py-CR₁=NR₂, R₁ or R₂=H, Me(CH₃), Ph) under nitrogen atmosphere are investigated by means of Mössbauer spectroscopy and magnetic measurements. It was found that the spin states of iron (II) in substitutited bis (2-pyridylimine) iron (II) thiocyanate are included: intermediate-spin (³T₁, S=1), mixed-spin of ⁵T₂(S=2)+³T₁ and spin incomplete transition of ⁵T₂?³T₁.     

Combinatorial Solid-Phase Synthesis of Structurally Complex Thiazolylhydantoines

A nine-step (!) solid-phase synthesis and subsequent cleavage with cyclization from the polymeric support were the keys to preparing high-quality molecular libraries of thiazolylhydantoines 1 from modified amino acid building blocks. Each step in the synthesis is different. Because the final cyclization cleaves only molecules that have been successfully constructed, the products obtained are pure. R¹, R²=alkyl; R³=aryl, arylO; R⁴=allyl.     

Crystal structures of ethylenediaminecadmium(II) tetracyanocadmate(II)-benzene(1/2) and ethylenediaminecadmium(II) tetracyanocadmate(II)

The crystal structure of ethylenediaminecadmium(II) tetracyanocadmate(II)-benzene(1/2),I, has been redetermined based on 1632 reflections collected anew for the crystal coated with epoxy resin, with a final conventionalR=0.038;I crystallizes in space groupP4₂22, witha=b=8.265(1) andc=15.512(3) Å, andZ=2. Ethylenediaminecadmium(II) tetracyanocadmate(II),II, is concluded to be identical with the residual metal complex host ofI, remaining after the liberation of the guest benzene molecules;II crystallizes from an aqueous solution containing bis- or tris-ethylenediaminecadmium(II) tetracyanocadmate(II) in space groupI4₁/acd, witha=b=14.366(1) andc=23.771(4) Å, andZ=16; refinement led to a conventionalR=0.043 for 1181 reflections. The bridging ethylenediamine ligand inI turns to a chelating one inII; dissociation and recombination should occur in the coordination sphere of the six-coordinate cadmium atom, whenII is derived fromI by the liberation of the guest molecules. Supplementary Data relating to this article are deposited with the British Library as Supplementary Publication No. SUP 82018 (30 pages).Dedicated to Professor H. M. Powell.     

Dinuclear nickel complexes of phenolbased dinucleating macrocycles: Synthesis,structure, and properties

Abstract

Dinuclear Ni₂(II,II) complexes with the formula [Ni₂(R^m,n)](ClO₄)₂ ((m,n)= (2,2) (1), (2,3) (2), (2,4) (3)) have been obtained where (R^m,n)^2- denotes the macrocycles containing two 2,6-bis(iminomethyl)-4-methylphenolate entities combined through two lateral chains, -(CH₂)_m- and -(CH₂)_n-, at the imino nitrogens. [Ni₂(R^2,2)](ClO₄)₂ (1) crystallizes in the triclinic crystal system, space group P 1, with Z=1, a=8.396(2) Å, b= 10.021(2) Å, c=8.104(2) Å, α=109.56(2)°, β=99.40(2)°, γ=79.89(2)°, V=628.5(3) ų and Z=1. The refinement converges with R=0.0384 and R_w=0.0415 for 2075 reflections with | Fo | > 3[sgrave](| Fo |). In the centrosymmetric [Ni₂(R^2,2)]²⁺, a pair of Ni(II) ions are bridged by two phenolic oxygens with the Ni···Ni separation of 2.801(1) Å. Each Ni assumes a planar configuration with Ni-O bond distances of 1.842(3) and 1.838(3) Å and Ni-N bond distances of 1.814(3) and 1.823(3) Å. In the solid state, 1 is diamagnetic (S₁=S₂=0) whereas [Ni₂(R^2,3)]-(ClO₄)₂ (2) and [Ni₂(R^2,4)](ClO₄)₂ (3) are of a mixed-spin (S₁=0, S₂=1). In DMSO and pyridine all the complexes assume high-spin (S₁=S₂=1). The Ni₂(II,II) complexes are electrochemically reduced in DMSO or pyridine to Ni₂(I,II) and Ni₂(I,I) complexes. The conproportionation constants of the Ni₂(I,II) complexes are determined to be 3.4X10⁴-1.2X10⁵ in DMSO and 1.6X10³-2.6X10⁵ in pyridine. The Ni₂(I,II) and Ni₂(I,I) complexes of 1–3 have been prepared by electrolysis in DMSO. The mixed-valent complexes of 1 and 2 are characterized by an intervalence (IV) transition band at 790 and ～ 700 nm, respectively, and belong to Class II using the classification of Robin and Day. The Ni₂(I,II) complex of 3 shows no IT band (Class I). The Ni₂(I,II) complexes of 1-3 show well-resolved ESR spectra due to the spin-coupled S_T = 1/2 ground-state. The Ni₂(I,I) complexes of 1-3 are all ESR- innocent probably due to the strong antiferromagnetic interaction.     

Triphenylantimony(V) o‐amidophenolates with unsymmetrical N‐aryl group for a reversible dioxygen binding

New triphenylantimony(V) o‐amidophenolates (AP‐Me,Et)SbPh₃ (1) and (AP‐Me,iPr)SbPh₃ (2) with unsymmetrically substituted N‐aryl groups and (AP‐Et,Et)SbPh₃ (3) with symmetrical N‐aryl group {AP‐R¹,R² is 4,6‐di‐tert‐butyl‐N‐[2‐alkyl(R¹),6‐alkyl(R²)‐phenyl]‐o‐amidophenolate dianion} were synthesized and characterized in detail. Complexes were examined for dioxygen activity. The unsymmetrical complexes 1 and 2 were found to form different geometrical isomers (A and B) of spiroendoperoxides [L‐R¹,R²(O₂)]SbPh₃ (4 and 5, respectively) with different dispositions of peroxide group and N‐aryl fragment (methyl and peroxide group are on the same side of the molecule in the less shielded isomer A, and on different sides in the more hindered isomer B). The isomer A prevails over isomer B, reflecting the possibility of steric control on the dioxygen‐binding reaction. Complex 3, where R¹ = R² = Et, formed the isomers 6A and 6B as 50:50. The ratio 4A:4B was 60:40 (for methyl‐ethyl containing complex 4) and it increased up to 80:20 for methyl‐isopropyl‐containing 5. The molecular structure of isomers 4A and 4B was confirmed by X‐ray analysis. Copyright © 2010 John Wiley & Sons, Ltd.     

Synthesis and reactions of fluorinated iminium salts

Different methods for the preparation of fluorinated iminium salts RR¹CNR²R³⁺MF₆^? (R=R¹=F ; R²=R³=CH₃, C₂H₅ M=As, Sb 4a ? c R=H, R¹=F; R²=R³=CH₃ M=As, Sb 5a, b R=R¹=CF₃; R²=H, R³=CH₃ M=Sb 12 R=R¹=CF₃; R²=R³=CH₃ M=As 14) are reported, the spectroscopic properties (IR, NMR) of the cations of these salts are briefly discussed. By F^?-addition to these salts, $\text{e.g.}$ to 16, perfluoroalkyl-bis(alkyl)-amines ($\text{e.g.}$ (CF₃)₂CFN(CH₃)₂ 15) can be prepared; from the methylation of CF₃NCF₂ bis(trifluoromethyl) methylamine (CF₃)₂NCH₃ (11) was obtained.     

Chemie polyfunktioneller Moleküle, 121. Mitt. Cyclopentadienylruthenium(II)-Komplexe desBis(diphenylphosphanyl)amins und -amids sowie des N,N-Bis(diphenylphosphanyl)-methylamins und -ethylamins

Summary This synthetic and structural work describes a series of half-sandwich cyclopentadienylruthenium(II) complexes containing the diphosphazane ligands [(C₆H₅)₂P]₂NR (R=H:Hdppa,1a;R=CH₃:dppma,1b;R=C₂H₅:dppea,1c;R=Li:Lidppa,1d). Treatment of1a, d with CpRuCl(PPh₃)₂ (Cp=⁵-C₅H₅, Ph=C₆H₅,2) in a molar ratio of 1:1 in boiling aromatic hydrocarbons affords the neutral complexes CpRuCl(Hdppa) (3) and CpRu(dppa)PPh₃ (6). The ionic complexes [CpRu(Ph₂P-NR-(PPh₂)PPh₃)Cl (R=CH₃:4a;R=C₂H₅:4b) are formed by the reaction of1b,c with2. One pot reactions of1a–c with2 in the presence of NH₄PF₆ in boiling CH₃OH give only the ionic compounds [CpRu(Ph₂P-NR-PPh₂)(PPh₃)]PF₆ (R=H, CH₃, C₂H₅;5a–c). The sulfur dioxide and hydride complexes [CpRu(Hdppa)¹-SO₂]Cl (7) and CpRu(H)Hdppa (8) are obtained by the interaction of3 with SO₂ or NaOCH₃. All compounds are characterized as far as possible by IR, Raman,³¹P{¹H} NMR,¹H NMR,¹³C{¹H} NMR, FD mass spectra, and their conductivity in CH₂Cl₂ solution. The X-ray crystal structures of3 and5a reveal that the P(1)-N(1)-P(2) angle of the coordinated ligand1a in both complexes is reduced to about 100° in comparison to free uncoordinated1a (119°). This small angle leads to a short P(1)–P(2) bond distance of 259.4 pm in3 and 254.3 pm in5a. The molecules of3 are connected by intermolecular (NH...Cl) hydrogen bridging bonds forming chains along thez axis of the unit cell. The crystals of5a contain two independent pairs of ions in the unit cell (Z=8). In5a no hydrogen bonds exist between the NH-groups and the PF ₆ ^– anions.

     

Crystal Structures of Mono-, Di-, and Triaminoguanidinium Sulfate,as Well as Azidoformamidinium Sulfate: Important Precursors for Syntheses of Nitrogen Rich Ionic Compounds

Bis(1-aminoguanidinium) sulfate monohydrate (AG₂SO₄ … H₂O, 1), bis(1,3-diamino-guanidinium sulfate (DAG₂SO₄, 2), bis(1,3,5-triaminoguanidinium) sulfate dihydrate (TAG₂SO₄ … 2 H₂O, 3) and bis(azidoformamidinium) sulfate (AF₂SO₄, 5) were synthesized and characterized by multinuclear NMR, IR, and Raman spectroscopy and elemental analysis. In the synthesis of 3, double protonated triaminoguanidinium sulfate (HTAGSO₄, 4) was obtained as a byproduct. The molecular structures of 1–5 in the crystalline state were determined by low-temperature single crystal X-ray diffraction. 1: orthorhombic, Pnma, a = 6.7222 (8) Å, b = 14.153 (2) Å, c = 11.637 (1) Å, V = 1107.1(2) ų, Z = 4, ρ_calc.= 1.586 g cm^?3 R₁ = 0.0442, wR₂ = 0.1007 (all data). 2: hexagonal, P6₁22, a,b = 6.6907 (1) Å, c = 43.4600 (8) Å, γ= 120°, V = 1684.86 (5) ų, Z = 6, ρ_calc.= 1.634 g cm^?3, R₁ = 0.0321, wR² = 0.0714 (all data). 3: monoclinic, C2/c, a = 9.6174 (8) Å, b = 22.858 (1) Å, c = 6.7746 (5) Å, β= 109.49 (1), V = 1404.0 (4) ų, Z = 4, ρ_calc.= 1.620 g cm_?3, R₁ = 0.0292, wR₂ = 0.0781 (all data). 4: monoclini c, P2₁/c, a = 8.9998 (9), b = 6.3953 (6), c = 13.3148(12) Å, β= 99.679 (8), V = 755.44 (13) ų, Z = 4, ρ_calc.= 1.778 g cm^?3, R₁ = 0.0305, wR₂ = 0.0809 (all data); 5: orthorhombic, Pbca, a = 11.3855 (9), b = 7.1032 (6), c = 12.807 (1) Å, V = 1035.74 (14) ų, Z = 4, ρ_calc.= 1.720 g cm^?3, R₁ = 0.0389, wR₂ = 0.0862 (all data).