Concerning the reaction of 2-(10-diazo-10H-anthracen-9-ylidene)-malonodinitrile and related compounds with the cryptohydride system formic acid-triethylamine

Summary The reaction of 2-(10-diazo-10H-anthracen-9-ylidene)-malonodinitrile (1) with the cryptohydride system formic acid - triethylamine was studied. The reaction product turned out to be anthracen-9-yl-acetonitrile (2a) instead of the expected 10-dicyanomethyl-9,10-dihydro-anthracene-9-yl formate. Compounds related to1 yielded in this reaction the corresponding 10-substituted anthracen-9-yl-acetonitriles. A mechanism of this reaction is proposed. The product of the formic acid promoted decomposition of1, compound3b, as well as its tautomer4b were also obtained.

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Zur Reaktion von 2-(10-Diazo-10H-anthracen-9-yliden)-malodinitril und Verwandten Verbindungen mit dem Kryptohydridsystem Ameisensäure - Triethylamin

Zusammenfassung Die Reaktion von 2-(10-Diazo-10H-anthracen-9-yliden)-malodinitril (1) mit dem Kryptohydridsystem Ameisensäure — Triethylamin wurde untersucht. Das Umsetzungsprodukt stellte sich als Anthracen-9-yl-acetonitril (2a) und nicht als erwartetes 10-Dicyanomethyl-9,10-dihydroanthracen-9-yl-format heraus. Verwandte Verbindungen reagierten in dieser Reaktion zu 10-substituierten Anthracen-9-yl-acetonitrilen. Ein Mechanismus für diese Reaktion wird vorschlagen. Das Produkt der durch Ameisensäure initiierten Zersetzung von1, Verbindung3b, wie auch sein Tautomer4b, wurden ebenfalls dargestellt.

     

Etude par polarisation nucleaire induite chimiquement de la reaction photochimique de l'anthracene avec des tetrahalogenomethanes

The photoreaction of anthracene with CCl₄, CCl₃Br or CBr₄ was studied by CIDNP. The primary products of the reaction (polyhalogeno 9,10-dihydro anthracenes) are thermally unstable, but evidence was shown for their existence. The initiating radical pair of this reaction is: $\text{9-chloro 10-anthryl/trichloromethyl}$^S. This study was extended to 9-methyl and 9,10-dimethyl anthracenes.     

Reactions of 2H-azirines with carbenoids from diazo esters: transformations of novel azirinium ylides

Thermocatalytic decomposition of diazo esters in the presence of 3-aryl-2H-azirines gives rise to azirinium ylides. The latter preferentially transform via isomerization into 2-azabuta-1,3-diene derivatives or, with excess diazo compound, via reaction with the Rh-carbenoid to form 3,4-dihydro-2H-pyrrole derivatives. In contrast, ylides generated from 2-monosubstituted or 2,2-disubstituted 3-phenyl-2H-azirines transform exclusively via isomerization into the corresponding 2-azabuta-1,3-dienes in high yields.     

InBr3 catalyzed three-component reactions of an aryldiazoacetate,an alcohol,and a carbonyl compound

InBr₃ promoted three-component reactions of an aryldiazoacetate, an alcohol, and an electron deficient carbonyl compound gave α,β-dihydroxyl acid derivatives in good yield with high diastereoselectivity. The reaction is proposed through a protic oxonium ylide trapping process. The reaction mechanism for the formation of the protic oxonium ylide via Lewis acid InBr₃ catalyzed diazo decomposition is suggested through a vinyl cationic intermediate.     

An Unprecedented Photochemical Reaction for Anthracene‐Containing Derivatives

A series of anthracene‐containing derivatives have been synthesised and characterised. The photochemical behaviour of these derivatives have been investigated by ¹H NMR spectroscopy. An unprecedented photolysis reaction for anthracene‐containing derivatives was observed in the case of anthracenes directly armed with a ‐CH₂O‐R group upon UV irradiation. The photolysis reaction process has been demonstrated to occur in three steps. Firstly, the anthracene‐containing derivatives are converted into the corresponding endoperoxide intermediate upon UV irradiation in the presence of air; then, the endoperoxide intermediate is decomposed to the corresponding starting compound and 9‐anthraldehyde; finally, 9‐anthraldehyde is further oxidised to anthraquinone. Additionally, the photolysis reaction of anthracene‐containing derivatives is significantly promoted in the presence of a thiacalix[4]arene platform.     

On the chemical nature of 10-dicyanomethylene-anthrone hydrazone

Summary The chemical nature of 10-dicyanomethylene-9-anthrone hydrazone was examined. It was shown that this compound bearing the conjugated ylidenemalononitrile fragment and hydrazonic moiety did not undergo transformations characteristic of ylidenemalononitriles,e.g., reduction andMichael addition, but possesses properties typical for hydrazones. Thus it could be hydrolyzed, acetylated, oxidized to yield the diazo compound, and reacted with acetone to form the corresponding azine. These properties were interpreted using semiempirical (AM1) and force field calculations.

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Über die chemische Natur von 10-Dicyanomethylen-anthronhydrazon

Zusammenfassung Die chemische Natur von 10-Dicyanomethylen-9-anthronhydrazon wurde untersucht. Es wurde gezeigt, daß diese Verbindung, welche konjugierte Ylidenmalononitril- und Hydrazonfragmente enthält, keine für Ylidenmalononitrile charakteristischen Reaktionen, wie Reduktion und Michaeladdition eingeht, dafür aber typische Hydrazoneigenschaften zeigte. Es konnte hydrolysiert, acetyliert, mit Aceton zum entsprechenden Azin umgesetzt und zur Diazoverbindung oxidiert werden. Diese Eigenschaften wurden mit Hilfe von semiempirischen (AM1) und Kraftfeld-Rechnungen interpretiert.

     

The thermal decomposition of N , N -dimethyl-3-oxaglutaramic acid and the kinetics of its second-stage thermal decomposition reaction

N,N-dimethyl-3-oxa-glutaramic acid was purified and characterized by ¹H-NMR, Fourier transform infrared spectroscopy (FT-IR) and elemental analysis. The thermal decomposition of the title compound was studied by means of thermogravimetry differential thermogravimetry (TG-DTG) and FT-IR. The kinetic parameters of its second-stage decomposition reaction were calculated and the decomposition mechanism was discussed. The kinetic model function in a differential form, apparent activation energy and pre-exponential constant of the reaction are 3/2 [(1−α)^1/3−1]⁻¹, 203.75 kJ·mol⁻¹ and 10^17.95s⁻¹, respectively. The values of ΔS ^≠, ΔH ^≠ and ΔG ^≠ of the reaction are 94.28 J·mol⁻¹·K⁻¹, 203.75 kJ·mol⁻¹ and 155.75 kJ·mol⁻¹, respectively. Supported by the National Natural Science Foundation of China (Grant No. 20106009)     

Carbenoid Reactions in Rhodium(II)-Catalyzed Decomposition of Iodonium Ylides

The intermediacy of metallocarbenes in decomposition reactions of iodonium ylides with [Rh₂(OAc)₄] was established by comparison with reactions of the corresponding diazo compounds. The sensitivity of the Rh^II-catalyzed intermolecular cyclopropane formation from substituted styrenes and bis(methoxycarbonyl)(phenyliodono)methanide ( 1a ) or dimethyl diazomalonate ( 1b ) is identical. The Hammett plot (with σ⁺) has a slope of ?0.47. Iodonium ylides and diazo compounds afford the same products in [Rh₂(OAc)₄]-catalyzed cyclopropane formations, cycloadditions, and intramolecular CH insertions, and exhibit the identical selectivity in intramolecular competitions for cyclopropane formation and insertion. The intramolecular CH insertion of the ylide 20c , when carried out in the presence of a chiral catalyst ([Rh₂{(?)-(S)-ptpa}₄]), results in formation of 21a having an ee of 67%, identical to the ee obtained with the diazo compound 20b .     

Intensification of Biocatalytical Processes by Synergistic Substrate Conversion. Fungal Peroxidase Catalyzed <Emphasis Type="Italic">N</Emphasis>-Hydroxy Derivative Oxidation in Presence of 10-Propyl Sulfonic Acid Phenoxazine

Many industrial pollutants, xenobiotics, and industry-important compounds are known to be oxidized by peroxidases. It has been shown that highly efficient peroxidase substrates are able to enhance the oxidation of low reactive substrate by acting as mediators. To explore this effect, the oxidation of two N-hydroxy derivatives, i.e., N-hydroxy-N-phenyl-acetamide (HPA) and N-hydroxy-N-phenyl-carbamic acid methyl ester (HPCM) catalyzed by recombinant Coprinus cinereus (rCiP) peroxidase has been studied in presence of efficient substrate 3-(4a,10a-dihydro- phenoxazin-10-yl)-propane-1-sulfonic acid (PPSA) at pH 8.5. The bimolecular constant of PPSA cation radical reaction with HPA was estimated to be (2.5 ± 0.2)·10⁷ M⁻¹ s⁻¹ and for HPCM was even higher. The kinetic measurements show that rCiP-catalyzed oxidation of HPA and HPCM can increase up to 33,000 times and 5,500 times in the presence of equivalent concentration of high reactive substrate PPSA. The mathematical model of synergistic rCiP-catalyzed HPA–PPSA and HPCM–PPSA oxidation was proposed. Experimentally obtained rate constants were in good agreement with those calculated from the model confirming the synergistic scheme of the substrate oxidation. In order to explain the different reactivity of substrates, the docking of substrates in the active site of the enzyme was calculated. Molecular dynamic calculations show that the enzyme–substrate complexes are structurally stable. The high reactive PPSA exhibited higher affinity to enzyme active site than HPA and HPCM. Furthermore, the orientation of HPA and HPCM was not favorable for proton transfer to the distal histidine, and different substrate reactivity was explained by these diversities.     

Single-Nitrogen Atom Incorporation into B=B Bond via the N=N Bond Splitting of Diazo Compound and Diazirine

Triboraazabutenyne 3 is synthesized by the reaction of diboraazabutenyne 1 with aryl boron dibromide followed by the reduction. The ligand exchange to replace phosphine on the terminal sp² B atom with carbene furnishes 4 . ¹¹B NMR, solid-state structures, and computational studies disclose that 3 and 4 feature the extremely polarized B=B bond. 4 readily splits the N=N bond of both diazo compound and diazirine under ambient conditions, whereby one nitrogen atom is incorporated into the B=B moiety leading to a neutral diboraazaallene 6 . The mechanism of the reaction between 4 and diazo compound is extensively investigated by density functional theory (DFT) calculations, as well as the isolation of an intermediate.     

Azirinium ylides from alkoxycarbonylcarbenoids and 2H-azirines: Generation and transformations

Dirhodium tetraacetate-catalyzed decomposition of diazo esters in the presence of 3-aryl-2H-azirines having no substituent in the 2-position gives rise to azirinium ylides which then undergo isomerization into 2-azabuta-1,3-diene derivatives or (in the presence of excess diazo ester) react with the corresponding rhodium carbenoid to form substituted 3,4-dihydro-2H-pyrroles. 2-Mono-and 2,2-disubstituted 3-phenyl-2H-azirines react with rhodium carbenoids generated from diazo esters to give azirinium ylides which are converted into the corresponding 2-azabuta-1,3-dienes.     

The addition of benzocyclobutenylidene to benzene : The facile rearrangement of spiro[benzocyclobutene-1,7'-cyclohepta-1',3',5'-triene] to 9a,10-dihydrobenz[α]azulene

Thermal decomposition of the sodium salts of benzocyclobutenone tosylhydrazone and 2-methylbenzocyclobutenone tosylhydrazone in benzene affords 9a,10-dihydrobenz[α]azulene 4 and trans-10-methyl-9a, 10-dihydrobenz[α]azulene 3, respectively. A mechanism involving initially the addition of the carbene benzocyclobutenylidene, or its 2-Me derivative, to the benzene ring is postulated. A proposed intermediate in the reaction, spiro [benzocyclobutene 1,7' cyclohepta-1',3',5'-triene] 12 has been synthesised, and shown to give rise to 4 under the reaction conditions. The rate of rearrangement of 12 → 4 has been measured, and the activation energy determined: E_a = 125.9 ± O.8 KJmol^?1 and A = 1.38 × lO¹⁴sec^?1. The mechanism for the rearrangement must involve ring opening of the benzocyclobutene moiety of 12 to give an o- xylylene intermediate which is postulated to possess considerable diradical character. At 71.8 °, this ring opening is 2.7 × 10⁶ times faster than the ring opening of the parent benzocyclobutene molecule. The decomposition of the sodium salt of 2-(7' -cyclohepta-1',3',5' trienyl)benzaldehyde tosylhydrazone has also been investigated and is shown to yield 4a,10-dihydrobenz[α]azulene, 9,10-dihydrobenz[α]azulene and 8,9-benzotricyclo [5.3.0.0^2.10]deca-3,5,8-triene. A mechanism involving intramolecular 1,3-dipolar addition of a diazo grouping to a cycloheptatriene Π-bond, followed by decomposition of the resulting pyrazoline intermediate, is proposed.     

New Methods of Preparative Organic Chemistry. Transfer of Diazo Groups

When an arenesulfonyl azide, particularly p-toluenesulfonyl azide, reacts, in the presence of a base, with a compound containing an active methylene group, the two hydrogen atoms of the active methylene group are replaced by a diazo group to form a diazo compound and an arenesulfonamide. The method may be used for the synthesis of the diazo derivatives of cyclopentadienes, cyclohexadienes, 1,3-dicarbonyl, 1,3-disulfonyl, and 1,3-ketosulfonyl compounds, ketones, carbonic acid esters, and β-iminoketones. Secondary reactions can lead to azo compounds and heterocycles such as 1,2,3-triazoles, 1,2,3-thiadiazoles, and pyrazolin-4-ones. Azidinium salts react in the same way, but in this case an acidic reaction medium is necessary, a fact that is sometimes advantageous.     

Syntheses and absolute stereochemistry of chiral 9,10-dihydro-9,10-ethanoanthracenes and their tricarbonylchromium complexes

Summary Several chiral mono- and disubstituted 9,10-dihydro-9,10-ethanoanthracenes have been prepared from the corresponding anthracenes. Most of them were separated into enantiomers by chromatography on cellulose triacetate (CTA) and their absolute chiralities established by chiroptical comparison (via their CD spectra) with key compounds of known configuration. From the laevorotatory 1,5-dibromo derivative16 the dextrorotatory dideuterio hydrocarbon (+)(9S, 10S)-20 was obtained.Complexation of 2,6-dimethyl 9,10-dihydro-9,10-ethanoanthracene (+)-25, obtained by enantio-selective chromatography onCTA [with its chirality (9R, 10R) deduced from optical comparison with the 2-monomethyl derivative of known configuration], with Cr(CO)₆ afforded two mono tricarbonyl-chromium complexes [endo(+)-26 andexo(+)-27] as well as the bis-exo,endo-complex (+)-28. Configurational assignments (exo, endo) are based on the absorption patterns of the bridge protons in the¹H-NMR spectra.On leave from Research Institute of Chemical Processing and Utilization of Forest Products, Nanking, P.R. China. mit Cr(CO)₆ lieferte zwei Mono-tricarbonylchrom-Komplexe [endo(+)-26 undexo(+)-27] neben dem Bis-exo,endo-Komplex (+)-28. Die konfigurative Zuordnung (exo,endo) war aufgrund der Absorptionen der Brücken-H-Atome in den¹H-NMR-Spektren möglich.     

Complexation with diol host compounds. Part 18. Structures and thermal analysis of trans-9,10-dihydroxy-9,10-di-p-tolyl-9,10-dihydroanthracene and its inclusion compounds with acetone,diethyl ether and pyridine

Abstract

The structure of the host compound trans-9,10-dihydroxy-9,10-di-p-tolyl-9,10-dihydroanthracene and those of its inclusion compounds with acetone, diethyl ether and pyridine have been elucidated. The non-porous α-phase of the host has a structure in which the molecules are packed in layers parallel to the (100) plane, but exhibit no intermolecular hydrogen bonding. The host:guest stoichiometry of each inclusion compound is 1:2, and the structures are each stabilised by O-H…O or O-H…N hydrogen bonds between host and guest. The thermal decompositions of the acetone and diethyl ether compounds are characterised by single endotherms of the guest-release reaction, but the pyridine inclusion compound has a more complex decomposition, characteristic of similar pyridine inclusion compounds.     

Stereospezifische Synthese und Isomerisierung der 10-Chlor-decahydroisochinoline. Decahydroisochinoline. IV. Teil

Treatment of cis- and trans-10-hydroxy-N-methyl-decahydroisoquinoline, ( 3a ) and ( 10a ) respectively, or N-methyl-Δ^9,10-octahydroisoquinoline ( 4 a ) with hydrogen chloride in acetic acid affords the thermodynamically more stable trans-isomer of 10-chloro-N-methyl-decahydroisoquinoline ( 1a ). On the other hand ring closure of β-(cyclohexen-1-yl)-ethylamines 11a or 11b with aqueous formaldehyde in the presence of chloride ions leads to the 10-cis-chlorides 2a or 2b in a kinetically controlled reactions.     

Structure and dehydrogenation of silylated dihydroanthracenes. A new route to 9- and 9,10-silylated anthracenes

Mono- and di-silylated derivatives of 9,10-dihydro anthracene have been prepared. The cis and trans isomers of the disilylated compounds were separated and their configurations assigned. Attempted dehydrogenation of the derivatives with sulphur and chloranil led to the formation of anthracene, whereas with n-BuLi/TMED high yields of the corresponding silylated anthracenes were obtained. This affords a new and improved method of synthesis of 9- and 9,10-silylated anthracenes. The mass spectra of the derivatives are also discussed.     

Catalytic Spectrophotometric Determination of Nanogram Amounts of Selenium(IV)

A method is proposed for the catalytic spectrophotometric determination of nanogram amounts of selenium(IV). The method is based on the reduction of nitrate with iron(II) ethylenediaminetetraacetate catalyzed by Se(IV) compounds. The reaction proceeds in several stages and yields iron(III) ethylenediaminetetraacetate, the nitrosyl complex of iron, nitrous acid, and other products. Nitrous acid enters into the diazotization reaction with aromatic amine. The resulting diazo compound is coupled with another aromatic amine to form the azo compound. 4-Nitroaniline is used as the diazo component, and N-diethyl-N-(1-naphthyl)ethylenediamine is used as the azo component. The molar absorptivity of the solution of the azo compound is 4.5 × 10⁴ at 540 nm. A kinetic method was developed for the determination of selenium(IV) in potable and natural waters with the use of the standard addition method. The detection limit of selenium by the proposed method is 0.1 ng/mL. In the determination of 0.2 and 2 ng/mL selenium, the relative standard deviation is 6 and 2%, respectively. The interfering effect of organic compounds dissolved in natural water is eliminated by the ultrasonic treatment of water samples.     

Thermal Decomposition Behavior and Non-isothermal Decomposition Reaction of Copper（ll） Salt of 4-Hydroxy-3,5-dinitropyridine Oxide and Its Application in Solid Rocket Propellant

The thermal decomposition behavior and kinetic parameters of the exothermic decomposition reactions of the title compound in a temperature‐programmed mode have been investigated by means of DSC, TG‐DTG and lower rate Thermolysis/FTIR. The possible reaction mechanism was proposed. The critical temperature of thermal explosion was calculated. The influence of the title compound on the combustion characteristic of composite modified double base propellant containing RDX has been explored with the strand burner. The results show that the kinetic model function in differential form, apparent activation energy E_a and pre‐exponential factor A of the major exothermic decomposition reaction are 1‐a,207.98 kJ*mol^?1 and 10^15.64 s^?1, respectively. The critical temperature of thermal explosion of the compound is 312.87 C. The kinetic equation of the major exothermic decomposition process of the title compound at 0.1 MPa could be expressed as: dα/dT=10^16.42 (1–α)e‐2.502×10⁴/T As an auxiliary catalyst, the title compound can help the main catalyst lead salt of 4‐hydroxy‐3,5dinitropyridine oxide to enhance the burning rate and reduce the pressure exponent of RDX‐CMDB propellant.     

Synthesis of heterocyclic homotriptycenes

A series of novel heterocyclic homotriptycenes bearing furan, thiophene, and pyridine rings, 7a-f, were synthesized by intramolecular dehydration reactions of 10,10-dihetarylmethyl-9,10-dihydroanthracen-9-ols 6a-f. In the presence of acids, the secondary alcohols 6a-f show different reactions which depend on the electron densities of the attached heterocyclic rings. The initially formed carbenium ions react in an electrophilic substitution with electron-rich heterocycles. The formation of a transannular bridge (1,7-elimination) leads to homotriptycenes in high yields. When the heterocyclic ring has a moderate electron density, two competitive reactions exist, which afford 9-monosubstituted anthracenes by 1,4-elimination or 9,10-disubstituted anthracenes by a rearrangement, respectively. Electron-deficient heterocycles undergo a disproportionation to give hydrocarbons and ketones.