Behaviour of 2-subst1tuted 6,8-dibromo-3,1-benzoxazin-4-ones towards o-phenylenediamine and anthranilic acid ; a case of unusual cleavage of 6,8-d1bromo-2-methyl-3,1-benzoxazin-4-one

6,8-Dibromo-2-methyl-3,l-benzoxazin-4-one (1) reacts with o-phenylenediamine to give a mixture of 3,5-dibromoanthranilic acid (2), 2-methylbenzimidazole (3) and 3-(o-aminophenyl)-6,8-dibromo-2-methylquinazolin-4-one (4). However, when the reaction was conducted in ethanol or in the absence of solvent at elevated temperature, a mixture of (2) & (3) was obtained. A similar cleavage of (1) took place when it was allowed to react with anthranilic acid yielding a mixture of (2) and N-acetylanthranilic acid (6). The reaction of o-phenylenediamine with 6,8-dibromo-2-phenyl-3,1-benzoxazin-4-one (7) proceeded normally to give 3-(o-aminophenyl)6,8-dibromo-2-phenylquinazolin-4-one (8) or 2-benzoyl-amino-3, 5-dibromo-N-(o-aminophenyl)benzamide (9), depending upon the reaction conditions.     

Exploratory chemistry of 3-aroylformamido-4-aryl-1,2,5-thiadiazoles

Apart from the previous report, the reaction of 3-(4-nitrobenzoylformamido)-4-(4-nitrophenyl)-1,2,5-thiadiazole ( 2a ) with m-chloroperbenzoic acid in chloroform at room temperature did not proceed, whereas at reflux temperature the same reaction gave 4-nitrobenzoic acid ( 5 ) (86%) and a minute amount of a mixture of 4-nitrobenzoylformamide ( 6 ) and 3-amino-4-(4-nitrophenyl)-1,2,5-thiadiazole ( 7a ). On the other hand the same reaction in a mixture of ethanol and chloroform (1:4) at room temperature gave 3-ethoxycarbamoyl-4-(4-nitrophenyl)-1,2,5-thiadiazole ( 8a ) (24%) as an isolable product. When 3-aroylformamido-4-aryl-1,2,5-thiadiazoles 2 in tetrahydrofuran were treated with various alkoxides in the corresponding alcohols at room temperature, 3-amino-4-aryl- 7 , 3-alkoxycarbamoyl-4-aryl- 8 , and 3-aryl-4-(aryl)(hydroxy)acetamido-1,2,5-thiadiazoles 9 were isolated. The ratios of which were dependent on the kind of bases and the solvent employed. Selected compounds 2 were allowed to react with phosphorus pentasulfide in the presence of pyridine at reflux to give 3-aryl-4-arylacetarnido-1,2,5-thiadiazoles 17 (55–64%), which were also produced by the reaction of 2 with either Lawesson's reagent or hydrogen sulfide gas in the presence of pyridine at reflux.     

Solid state synthesis of lithiated manganese oxides from mechanically activated Li2CO3–Mn3O4 mixtures

The solid state formation of lithium manganese oxides has been studied from the thermal decomposition of mixtures Li₂CO₃–Mn₃O₄ with X_Li (lithium cationic fraction)=0.33 (LiMn₂O₄), 0.50 (LiMnO₂) and 0.66 (Li₂MnO₃). The analysis of the reactivity has been performed mainly by thermoanalytical (TG/DSC) and diffractometric (XRPD) techniques either on physical mixtures and on mixtures subjected to mechanical activation by high energy milling. At X_Li=0.33, the cubic lithium manganese spinel oxide (LiMn₂O₄) forms in air. TG measurements showed that the reaction starts at a considerably lower temperature in the activated mixture. By variable temperature X-ray diffraction it has been assessed that, upon mechanical activation, LiMn₂O₄ forms directly and its formation is completed within 700 °C whereas, starting from a physical mixture, the formation goes through Mn₂O₃ and is complete only at 800 °C. At T>820 °C LiMn₂O₄ reversibly decomposes to LiMnO₂ and Mn₃O₄ with an enthalpy of 30.05 kJ mol⁻¹ of LiMn₂O₄. At X_Li=0.50, by annealing under nitrogen flow for 6 h at 650 °C the activated mixture, the orthorhombic LiMnO₂ is formed. Such a formation goes through a mixture of LiMnO₂ and LiMn₂O₄. The enthalpy of LiMnO₂ solid state formation from the activated mixture has been determined to be 57.4 kJ mol⁻¹ of LiMnO₂. At X_Li=0.66 in air the mechanical activation considerably lowers the temperature within the monoclinic phase Li₂MnO₃ forms. Besides the reaction enthalpy could be determined as 40.13 kJ mol⁻¹ of Li₂MnO₃. The reaction, when performed under nitrogen flow, goes through the formation of LiMnO₂. Such a first stage of the reaction is affected by the temperature of reaction rather than by mechanical activation. The activation greatly enhances the second stage of the reaction leading from LiMnO₂ to Li₂MnO₃.     

Skeletal transformations of perfluoro-1-ethyl-1-phenylbenzocyclobutene in the reaction with antimony pentafluoride

Interaction of perfluoro-1-ethyl-1-phenylbenzocyclobutene with SbF₅ at room temperature gives, after treatment of the reaction mixture with H₂O, perfluoro-4-[1-(2-methylphenyl)propylidene]cyclohexa-2,5-dienone as a main product. The reaction at 90-95 °C leads, after treatment with H₂O, to a mixture of perfluorinated 9-ethyl-9-methyl-1,2,3,4-tetrahydro-9H-fluorene, 9-ethyl-4a-methyl-4,4a-dihydrofluoren-1-one, 3-ethyl-3-phenylphthalide, 1-hydroxy-2-methyl-1-phenylindan, 3-methyl-2-phenylindenone and small amounts of other products.     

Effect of quenching on the methane coupling reaction

The effect of reaction mixture quenching on C₂ product formation in the methane coupling reaction on La₂O₃/CaO is disclosed. For reaction with the mixture (vol. %): 54.5 CH₄, 9.1 O₂ and 36.4 N₂ at 973 K, quenching of products results in a two-fold decrease in C₂ product yield. The results give evidence that in methane oxidative coupling methyl radical formation can occur in the gas phase to an extent comparable with that on the catalyst surface. The effect described must be taken into account in the case of an industrial application of methane oxidative coupling, too, because quenching is a regular procedure in the high temperature oxidative processes.     

Facile synthesis of 3-aryl-1-((4-aryl-1,2,3-selenadiazol-5-yl)sulfanyl)isoquinolines

A new series of 1,2,3-selenadiazoles containing an aryl or a 3-arylisoquinoline sulfanyl moiety at carbons 4 and 5, respectively, was prepared by cyclization of the respective semicarbazones in the presence of selenium(II) oxide and tetrahydrofuran at 70–75°C. Semicarbazones required for the reaction were obtained from 2-((3-arylisoquinolin-1-yl)sulfanyl)-1-phenylethanones, I, by a reaction with semicarbazide hydrochloride in ethanol/water mixture and potassium acetate base.     

Hydrolytic reactions of diribonucleoside 3',5'-(3'-N-phosphoramidates): kinetics and mechanisms for the P-O and P-N bond cleavage of 3'-amino-3'-deoxyuridylyl-3',5'-uridine

Hydrolytic reactions of 3'-amino-3'-deoxyuridylyl-3',5'-uridine (2a), an analogue of uridylyl-3',5'-uridine having the 3'-bridging oxygen replaced with nitrogen, have been followed by RP HPLC over a wide pH range. The only reaction taking place under alkaline conditions (pH > 9) is hydroxide ion-catalyzed hydrolysis (first-order in [OH(-)]) to a mixture of 3'-amino-3'-deoxyuridine 3'-phosphoramidate (7) and uridine (4). The reaction proceeds without detectable accumulation of any intermediates. At pH 6-8, a pH-independent formation of 3'-amino-3'-deoxyuridine 2'-phosphate (3) competes with the base-catalyzed cleavage. Both 3 and in particular 7 are, however, rather rapidly dephosphorylated under these conditions to 3'-amino-3'-deoxyuridine (5). In all likelihood, both 3 and 7 are formed by an intramolecular nucleophilic attack of the 2'-hydroxy function on the phosphorus atom, giving a phosphorane-like intermediate or transition state. Under moderately acidic conditions (pH 2-6), the predominant reaction is acid-catalyzed cleavage of the P-N3' bond (first-order in [H(+)]) that yields an equimolar mixture of 5 and uridine 5'-phosphate (6). The reaction is proposed to proceed without intramolecular participation of the neighboring 2'-hydroxyl group. Under more acidic conditions (pH < 2), hydrolysis to 3 and 4 starts to compete with the cleavage of the P-N bond, and this reaction is even the fastest one at pH < 1. Formation of 2'-O,3'-N-cyclic phosphoramidate as an intermediate appears probable, although its appearance cannot be experimentally verified. The rate constants for various partial reactions have been determined. The reaction mechanisms and the effect that replacing the 3'-oxygen with nitrogen has on the behavior of the phosphorane intermediate are discussed.     

Photoinduced and thermal reactions of α‐cyano‐β‐bromomethylcinnamide with 1‐benzyl‐1,4‐dihydronicotinamide

The photoinduced reaction of a mixture of (Z)‐α‐cyano‐β‐bromomethylcinnamide (1) and (E)‐α‐cyano‐β‐bromomethylcinnamide (2) with 1‐benzyl‐1, 4‐dihydronicotinamide produces a mixture of the (E)‐ and (Z)‐ isomers of α‐cyano‐β‐methylcinnamide (3 and 4). Using spin‐trapping technique for monitoring reactive intermediate, it is shown that the reaction proceeds via electron transfer‐debromination‐H abstraction mechanism. The thermal reaction of the same substrate with BNAH at 60°C in the dark gives three products: the (E)‐ and (Z)‐isomers of α‐cyano‐β‐methylcinnamide and a dehydrodimeric product; 2, 7‐dicyano‐3, 6‐diphenylocta‐2, 4, 6‐trien‐1, 8‐dioic amide (7). Based on product analysis, scavenger experiment and cyclic voltammetry, an electron transfer‐debromination‐disproportionation mechanism is proposed.     

Increased activity of in situ catalysts for alkyne metathesis

[reaction: see text] Reaction of an enyne (1,1-diphenyl-pent-1-ene-3-yne) with a preheated mixture of Mo(CO)6/4-chlorophenol/3-hexyne at 130 degrees C furnished 1,1,6,6-tetraphenylhex-1,5-diene-3-yne in an 80% yield. If the starting material was heated with a mixture of Mo(CO)6 and 4-chlorophenol under identical conditions, no reaction was observed.     

Physicochemical transformations during synthesis of double K−Zr phosphates in a melt of potassium nitrate

Double phosphates of K and Zr with three-dimensional and layered structure were synthesized in a melt of potassium nitrate in the temperature range of 300–550°C. The double phosphates were formed with participation of three components of a reaction mixture: ZrOCl₂·8H₂O−(NH₄)₂HPO₄−KNO₃, in which potassium nitrate was both an active component of the reaction mixture and the reaction medium. The influence of the nature of the starting reagents on the composition of the reaction products and on the sequence and stoichiometry of the reactions proceeding, in the reaction mixture were studied by thermogravimetry and mass-spectrometry. Translated fromIzvestiya Akademii Nauk. Seriya Khimicheskaya, No. 4, pp. 666–670, April, 1997.     

Synthesis of Enol Methyl Ethers of 3-Acetyl-6,6-dimethyltetrahydrothiopyran-2,4-dione and Their Reactions with Amines

The reaction of 3-acetyl-6,6-dimethyltetrahydrothiopyran-2,4-dione with diazomethane furnishes a mixture of 3-acetyl-6,6-dimethyl-4-methoxy-5,6-dihydro-2H-thiopyran-2-one and 3-acetyl-6,6-dimethyl- 2-methoxy-5,6-dihydro-2H-thiopyran-4-one in 2:3 ratio, whereas in reaction with dimethyl sulfate in the presence of potassium carbonate forms a mixture of the same products in 9:1 ratio. In both reactions the overall yield of ethers amounts to 50%. Treating of regioisomeric enol methyl ethers with pyrrolidine, o-toluidine, and allylamine provides the corresponding endocyclic enaminodiketones.     

Synthesen und chemische Eigenschaften neuer «Donor-Akzeptor»-stabilisierter Molekülsysteme mit zentraler Bicyclo [4.4.1]undeca-l (10), 3,6,8-tetraen-2,5-diyliden-Gruppe

Syntheses and Chemical Properties of New ‘Donor-Acceptor’-stahilized Molecular Systems with a Central Bicyclo[4.4.1] undeca-l(10).3,6,8-tetraene-2,5-diylidenc Group The synthesis of X-methyl-2-(5-oxobicyclo[4.4.1]undeca-l)10(,3,6,8-tetraen-2-yliden)-l,3-benzodithiol ( 4 ) is described starting with the keto-enol mixture 2 and 5-methyl-1,3-benzodithiolium perchlorate. Under rearomatization of the central frame protonation of 4 yields the salt 4c. The reaction of 4 with dicyanoketene gives the ‘push-pull-substituted’ 5 , and with 9-carbonylfluorene the fulvalene derivative 7 , which can be protonated by CF₃CO₂H at C(9″) to the salt 8. The reaction of 2-methylthio-l,3-dithiolium jodide 9 with the keto-enol mixture 2 yields 10 , which, on protonation at the carbonyl group by CF₃CO₂H, gives the salt 11 under rearomatization. The spectral data of the new compounds 4, 4c, 5, 7, 8, 10 and 11 are reported and discussed.     

Reactions of tetrafluorophthalic and difluoropyromellitic acids with sulphur tetrafluoride

Fluorination of tetrafluorophthalic acid (1) with an SF₄/HF mixture at 190–300°C afforded,beside the expected perfluoro-o-xylene (2) and perfluoro-o-toluyl fluoride (4), considerableamounts of octafluoro-1,3-dihydroisobenzofuran (3). The reaction with difluoropyromelliticacid (5) at 190°C gave a mixture of perfluoro-2,4,5-trimethylbenzoyl fluoride (9),perfluoro-2,5-dimethylterephthaloyl difluoride (10a), perfluoro-2,4-dimethylisophthaloyl difluoride(10b) and perfluoro-5-methyl-6-fluoroformyl-1,3-dihydroisobenzofuran (11), but at 300°C perfluorodurene (6), perfluoro-5,6-dimethyl-1,3-dihydroisobenzofuran (7) and perfluoro-2,4,5-trimethylbenzoyl fluoride (9) were obtained in a 3:1:0.8 ratio.     

Formation of pyrrole derivatives through aminolysis of 2-azetidinone derivatives

A mixture of 3-(α,β-epoxyisopropyl)-1-phenyl-2-azetidinone and benzylamine was heated in a sealed tube at 120–130° yielding 4-anilinomethyl-1-benzyl-3-hydroxy-3-methyl-2-pyrrolidinone as a mixture of diastereoisomers. By this method, 4-anilinomethyl-3-hydroxy-3-methyl-1-phenyl-2-pyrrolidinone and 4-anilinomethyl-3-hydroxy-3-methyl-1-(3,4-dimethoxyphenethyl)-2-pyrrolidinone were obtained by using aniline and 3,4-dimethoxyphenethylamine, respectively, instead of benzylamine. The reaction of 4-formyl-1-phenyl-2-azetidinone with 3,4-dimethoxyphenethylamine afforded 4-anilino-1-(3,4-dimethoxyphenethyl)-2,3-dihydro-2-oxopyrrole. In a similar fashion, the 1-n-butyl and 1-isobutyl analogues were obtained by the use of n-butylamine and isobutylamine, respectively, instead of 3,4-dimethoxyphenethylamine.     

Alkylation of Carboxylate Salts of Acidic Herbicides for Gas Chromatographic Analysis

Abstract

The methyl esters of 2-methoxy-3, 6-dichlorobenzoic acid and three phenoxyacetic acids were prepared by the admixture of an excess of both methyl iodide and anhydrous alkali-metal carbonate to a solution of the carboxylic acids in acetone. The reaction was completed within the shortest period of time when cesium carbonate was used, and the reaction mixture was injected without further work-up into a gas chromatograph fitted with a flame ionization detector. Further reduction of reaction time was achieved by heating the mixture to 50°C and by ultrasonic treatment; this technique is also suitable for esterification of microliter quantities and obviates the need for a microrefluxer. Butylesters of 2, 4-D and 2, 4, 5-T were prepared in an analogous manner. The methyl esters of 2, 4-D and 2, 4, 5-T, and the butyl ester of 2, 4-D were obtained in better than 90% yield.     

Kinetic scheme of homogeneous acid-catalyzed transformation of isopentenols

The reactions occurring in an equilibrium mixture of 3-methyl-1-buten-3-ol and 3-methyl-2-buten-1-ol in 24–49 % aqueous solutions of H₂SO₄ yield isoprene, 3-methyl-3-buten-1-ol, isobutylene, formaldehyde, 3-methylbutane-1,3-diol. Isobutylene is rapidly hydrated to give 2-methylpropan-2-ol. The presence of formaldehyde in the reaction mixture indicates that the transformations involve the reverse Prins reaction. On the basis of experimental and literature data, two most probable reaction schemes were suggested.Translated fromIzvestiya Akademii Nauk. Sertya Khimicheskaya, No. 5, pp. 867–870, May, 1995.     

Hydrogen storage properties of Li-Mg-N-H systems with different ratios of LiH/Mg(NH2)2

In this work, the hydrogen desorption and structural properties of the Li-Mg-N-H systems with different LiH/Mg(NH2)2 ratios are systemically investigated. The results indicate that the system with the LiH/Mg(NH2)2 ratio of 6/3 transforms into Li2NH and MgNH, and then, the mixture forms an unknown phase by a solid-solid reaction, which presumably is the ternary imide Li2Mg(NH)2; the system with the LiH/Mg(NH2)2 ratio of 8/3 transforms into 4Li2NH and Mg3N2 after releasing H2 at T < 400 degrees C; the system with the LiH/Mg(NH2)2 ratio of 12/3 transforms into 4Li3N and Mg3N2 after releasing H2 at T > 400 degrees C, where the LiMgN phase is formed by the reaction between Li3N and Mg3N2. The characteristics of the phase transformations and the thermal gas desorption behaviors in these Li-Mg-N-H systems could be reasonably explained by the ammonia mediated reaction model, irrespective of the difference in the LiH/Mg(NH2)2 ratios.     

Alkene oxidation by a platinum oxo complex and isolation of a platinaoxetane

Oxo complex [(1,5-COD)4Pt4(mu3-O)2Cl2](BF4)2 (1) reacts readily with ethylene and norbornylene. The ethylene reaction yields acetaldehyde and a 1:1 mixture of (1,5-COD)Pt(Cl)(CH2CH3) (2) and [(1,5-COD)Pt4(eta3-CH2CHCH(CH3))](BF4) (3), while the norbornylene reaction yields a platinaoxetane complex, the first metallaoxetane to be obtained from the reaction of an oxo complex and an alkene.     

Synthesis of 1‐Methyl‐6,10‐diphenylheptalene Derivatives

The reduction of heptalene diester 1 with diisobutylaluminium hydride (DIBAH) in THF gave a mixture of heptalene‐1,2‐dimethanol 2a and its double‐bond‐shift (DBS) isomer 2b (Scheme 3). Both products can be isolated by column chromatography on silica gel. The subsequent chlorination of 2a or 2b with PCl₅ in CH₂Cl₂ led to a mixture of 1,2‐bis(chloromethyl)heptalene 3a and its DBS isomer 3b . After a prolonged chromatographic separation, both products 3a and 3b were obtained in pure form. They crystallized smoothly from hexane/Et₂O 7 : 1 at low temperature, and their structures were determined by X‐ray crystal‐structure analysis (Figs. 1 and 2). The nucleophilic exchange of the Cl substituents of 3a or 3b by diphenylphosphino groups was easily achieved with excess of (diphenylphospino)lithium (=lithium diphenylphosphanide) in THF at 0° (Scheme 4). However, the purification of 4a / 4b was very difficult since these bis‐phosphines decomposed on column chromatography on silica gel and were converted mostly by oxidation by air to bis(phosphine oxides) 5a and 5b . Both 5a and 5b were also obtained in pure form by reaction of 3a or 3b with (diphenylphosphinyl)lithium (=lithium oxidodiphenylphospanide) in THF, followed by column chromatography on silica gel with Et₂O. Carboxaldehydes 7a and 7b were synthesized by a disproportionation reaction of the dimethanol mixture 2a / 2b with catalytic amounts of TsOH. The subsequent decarbonylation of both carboxaldehydes with tris(triphenylphosphine)rhodium(1+) chloride yielded heptalene 8 in a quantitative yield. The reaction of a thermal‐equilibrium mixture 3a / 3b with the borane adduct of (diphenylphosphino)lithium in THF at 0° gave 6a and 6b in yields of 5 and 15%, respectively (Scheme 4). However, heating 6a or 6b in the presence of 1,4‐diazabicyclo[2.2.2]octane (DABCO) in toluene, generated both bis‐phosphine 4a and its DBS isomer 4b which could not be separated. The attempt at a conversion of 3a or 3b into bis‐phosphines 4a or 4b by treatment with t‐BuLi and Ph₂PCl also failed completely. Thus, we returned to investigate the antipodes of the dimethanols 2a, 2b , and of 8 that can be separated on an HPLC Chiralcel‐OD column. The CD spectra of optically pure (M)‐ and (P)‐configurated heptalenes 2a, 2b , and 8 were measured (Figs. 4, 5, and 9).     

Oxidative addition of <Emphasis Type="Italic">N</Emphasis>-aminophthalimide to styryl-1,2,4-oxadiazoles

The oxidation of N-aminophthalimide with lead tetraacetate in the presence of 5-[(E)-2-arylethenyl]-3-(4-methylphenyl)-1,2,4-oxadiazoles and 5-(4-methylphenyl)-3-[E)-2-phenyl-ethenyl]-1,2,4-oxadiazole led to the formation of the corresponding (3-aryl-1-phthalimidoaziridin-2-yl)-(4-methylphenyl)-1,2,4-oxadiazoles. In the reaction with 3,5-distyryl-1,2,4-oxadiazole a mixture was obtained of two regioisomeric monoadducts and a diadduct in the ratio 80 : 15: 5; at the use of 3 equiv of the aziridinating reagents only diadduct was isolated as a mixture of two diastereoisomers in the ∼3 : 2 ratio that were separated by recrystallization.