Synthesis and reactions of pyrido[3,2,1‐jk]carbazole‐4,6‐diones

Pyrido[3,2,1‐jk]carbazoles 1 , synthesized from carbazoles and alkyl‐ or arylmalonates, gave regioselective electrophilic substitution reactions at position 5 such as chlorination to 5‐chloro derivatives 2 , nitration to 5‐nitro compounds 3 , or hydroxylation to 5‐hydroxy derivatives 4 . 5‐Hydroxy compounds 4 gave on treatment with strong bases ring contraction to 5 , 6 or the ring opening product 7 . Exchange of the chloro group in 2 with azide or amines gave the corresponding azides 8 and the 5‐amino derivatives 9 and 10 . Alkylation of 1 with benzyl chloride or allyl bromide resulted in the formation of 5‐C‐alkylated products 11 together with 4‐alkyloxy derivatives 12 . J. Heterocyclic Chem., 48, 1039 (2011).     

Behavior of 2‐iminothiazolidin‐4‐one with different reagents

Annulations of 2‐imino‐4‐thiazolidinone ( 5 ) via cycloaddition followed by cyclocondensation reaction with 1,3‐diphenylpropenone ( 6 ), benzylidenemalonate, and 1,2‐bis(chloromethyl)benzene gave 7 , 19 and 20 , respectively. Reaction of 5 with suitable electrophiles (Mannich bases of arylalkanone), 1,4‐dichlorobenzene (diarylmethylation), and formylation afforded 8 / 9 , 21 / 22 , and 23 , respectively. J. Heterocyclic Chem., (2011).     

Computational study of FOX‐7 synthesis in a solvated reaction system

Ethene and two kinds of nitrating reagents (HNO₃ and N₂O₅) in a variety of solvents were included in respective molecular systems, and each underwent a two‐stage electrophilic and free radical nitro‐substitution reaction to obtain the corresponding nitroethene compounds. Subsequent halogenation (using Cl₂ and Br₂) and amination (using NH₃) were then performed in solvents, also by electrophilic and radical substitution, to produce the desired 1,1‐diamino‐2,2‐dinitroethene (FOX‐7) derivatives. The reaction energy barrier in the nitration stage for obtaining each kind of mononitro ethene exhibited a stepwise decreasing trend when the reaction was carried out in H₂O‐solvated and CH₃OH‐solvated systems, no matter what nitrating agent was used. Related energy barrier data showed that the nitration reaction is more feasible in an H₂O‐solvated than a CH₃OH‐solvated system. The modeling results suggested that N₂O₅ is the better agent for nitration to proceed in water, bromine is suitable for halogenation, and the bromine derivatives are convenient for further amination in an H₂O‐solvated system. © 2010 Wiley Periodicals, Inc. Int J Quantum Chem, 2011     

Novel Approach for Rapid and Efficient Synthesis of 2‐(3‐(4‐Aryl)‐1‐isonicotinoyl‐4,5‐dihydro‐1H‐pyrazol‐4‐yl)‐3‐phenylthiazolidin‐4‐one Derivatives and Screened Their Antimicrobial Activity

A series of compounds, viz. 2‐(3‐(4‐aryl)‐1‐isonicotinoyl‐4,5‐dihydro‐1H‐pyrazol‐4‐yl)‐3‐phenylthiazolidin‐4‐one 4 ( a – n ), have been synthesized by reaction of 3 ( a – n ) with thioglycolic acid in the presence of zinc chloride. Compounds 3 ( a – n ) have been synthesized by amination of formylated pyrazoles 2 ( A – B ), which were synthesized by formylation of 1 ( A – B ) by Vilsmeier–Haack reagent (POCl₃/DMF). Compounds 1 ( A – B ) were synthesized by condensation of hydrazide and substituted acetophenones under conventional method and microwave irradiation method. These compounds were identified on the basis of melting point range, Rf values, infrared, ¹H NMR, and mass spectral analysis. These compounds were evaluated for their in vitro antimicrobial activity, and their minimum inhibitory concentration was determined. Among them, compound 4b and compound 4l possess appreciable antimicrobial and antifungal activities. Antibacterial activity results showed that compounds containing electron‐withdrawing groups were more active than compounds containing electron‐releasing groups.     

Synthesis of Aldehydo Sugar (4‐oxoquinazolin‐2‐yl)hydrazones and their transformation into 1‐(alditol‐1‐yl)‐1,2,4‐triazolo‐[4,3‐a]quinazolin‐5(4H)‐ones

A series of the aldehydo‐sugar hydrazones 4a‐d and 5a‐d were prepared by the reaction of 2‐hydrazino‐quinazolin‐4(3H)‐one ( 1 ) and 3‐ethyl‐2‐hydrazinoquinazolin‐4(3H)‐one ( 2 ) with aldoses 3a‐d . Treatment of hydrazones 4a‐d and 5a‐d with acetic anhydride in pyridine gave hydrazone acetates 6a‐d and 7a‐d . Compounds 7a‐d were also prepared by ethylation of 6a‐d . Reaction of compounds 4a‐d and 5a‐d with hot ethanolic ferric chloride led to oxidative cyclization to angular ring systems 8a‐d and 9a‐d rather than to the linear system 10 . Acetylation of 8a‐d afforded the per‐O, N‐acetyl derivatives 11a‐d , which were converted into the corresponding ethyl derivatives 12a‐d . Compounds 12a‐d were identical with the acetylation products derived from 9a‐d .     

Carbon‐Based Metal‐Free Catalysts for Electrocatalysis beyond the ORR

Besides their use in fuel cells for energy conversion through the oxygen reduction reaction (ORR), carbon‐based metal‐free catalysts have also been demonstrated to be promising alternatives to noble‐metal/metal oxide catalysts for the oxygen evolution reaction (OER) in metal–air batteries for energy storage and for the splitting of water to produce hydrogen fuels through the hydrogen evolution reaction (HER). This Review focuses on recent progress in the development of carbon‐based metal‐free catalysts for the OER and HER, along with challenges and perspectives in the emerging field of metal‐free electrocatalysis.     

Influence of FeCl3‐modified chloroaluminate ionic liquids on long‐chain alkenes alkylation

The influence of anhydrous ferric chloride on the catalytic properties of chloroaluminate ionic liquids catalyst for Friedel–Crafts alkylation was investigated. The catalysts were characterized by Fourier‐transform infrared (FT‐IR) (acetonitrile molecule as probe), specific gravity, and ²⁷Al NMR. Besides, the effect of the mass ratio of FeCl₃ to AlCl₃, catalysts dosage, toluene/olefin molar ratio, reaction temperature, and reaction time on long‐chain alkenes alkylation were investigated thoroughly. And bromine value and high‐performance liquid chromatography (HPLC) were employed as the evaluation method for alkylation products. It was observed that the addition of anhydrous ferric chloride results in improvement in terms of Lewis acid and its catalytic recyclability. Among these catalysts studied, the catalyst modified with 1.0 wt.% anhydrous FeCl₃ showed the best catalytic performance in terms of yield and stability, which can be attributed to the formation of new stronger acidic ions [Al₂FeCl_l0]^? when the added ferric chloride reacts with acidic ions [Al₂Cl₇]^?.     

Selective and Efficient Formylation of Indoles (C3) and Pyrroles (C2) Using 2,4,6‐Trichloro‐1,3,5‐Triazine/Dimethylformamide (TCT/DMF) Mixed Reagent

This study introduces an efficient method for the selective formylation of indoles and pyrroles at the positions of C(3) and C(2), respectively. The mixture of three equivalents of N ,N‐dimethylformamide and one equivalent of 2,4,6‐trichloro‐1,3,5‐triazine (cyanuric chloride) generates an easy handling formylating agent for the efficient formylation of these classes of compounds to give the corresponding aldehydes under mild reaction conditions. This procedure was highly efficient, and a range of formylated indoles and pyrroles were obtained in good to excellent yields.     

Thermal cyclization of 4‐azido‐3‐nitropyridines to furoxanes

4‐Chloro‐3‐nitro‐2‐pyridines 3 and 10, obtained from 4‐hydroxy‐2‐pyridones 1 and 8 after nitration and chlorination, gave with sodium azide 4‐azido‐3‐nitropyridines 4 and 11 , which cyclized on thermolysis to furoxans 6 and 12 . Desoxygenation of the furoxan 6 with triphenylphosphane gave the furazan 7 . Thermal decomposition conditions of the azide 4 and the desoxygenation reaction of 6 to 7 were studied by differ ential scanning calorimetry (DSC).     

Sur la synthèse de chloro-3 indolinones a partir de β-nitrostyrènes diversement substitués

When treated with acetyl chloride and ferric chloride in methylene chloride, at 0°, monosubstituted β-nitrostyrene derivatives such as 2,3 or 4-methyl, -chloro or -fluoro and 3-nitro-β-nitrostyrenes cyclize into the new corresponding 3-chloro-1,3-dihydro-2H-indol-2-one. Reaction with other metal chlorides such as aluminum chloride and titanium tetrachloride does not lead to these heterocyclic derivatives but only produces N-acetyl-N-hydroxy-α-chlorobenzeneacetamides and/or N-(acetyloxy)-α-chlorobenzeneethanimidoyl chlorides.     

5‐Unsubstituted Pyrido[3,2,1‐jk]carbazol‐6‐ones: Syntheses,Substitution, and Cyclization Reactions

The synthesis of the 5‐unsubstituted pyrido[3,2,1‐jk]carbazol‐6‐one 4 can be achieved by the reaction of carbazole ( 1 ) and malonate derivatives, either in a three‐step synthesis via 5‐acetyl‐pyridocarbazolone 3 or in a one‐step reaction from 1 and malonic acid/phosphoryl chloride. The 5‐acetyl derivative 5 can be transformed via a tosylate intermediate to 4‐azido‐pyridocarbazolone 11 , which cyclizes by thermal decomposition to the isoxazolo‐pyrido[3,2,1‐jk]carbazolone 12 . The thermolysis conditions were investigated by DSC. Nitration of pyridocarbazolone 4 and subsequent introduction of azide leads to azido derivative 23 , which cyclizes on thermolysis to furazan‐oxide derivative 24 . Again, the thermolysis conditions were investigated by DSC. 5‐Chloro‐5‐nitro‐pyrido[3,2,1‐jk]carbazole‐4,6‐dione, obtained from 4 by subsequent nitration and chlorination, forms by exchange of both 5‐substituents 5,5‐dihydroxy‐pyridocarbazoledione 17 , which acylates phenol to give 5‐hydroxy‐5‐(p‐hydroxyphenyl)‐pyridocarbazoledione 20 . Acid‐catalyzed cyclodehydration of 20 forms a highly fused benzofuro‐pyridocarbazole 21 . Another C–C coupling at position 5 starts from 4‐chloro‐5‐nitro‐pyridocarbazolone 22 and diethyl malonate 2a , which forms the diethyl (nitrocarbazolyl)malonate 25 . With dimethyl malonate 2c , the intermediate dimethyl (nitrocarbazolyl)malonate gives on thermolysis the (nitrocarbazolyl)acetate 27 by loss of one ester group.     

Synthesis of 1‐methyl‐, 4‐nitro‐, 4‐amino‐and 4‐iodo‐1,2‐dihydro‐3H‐pyrazol‐3‐ones

4‐Aminopyrazole‐3‐ones 4b, e, f were prepared from pyrazole‐3‐ones 1b‐d in a four‐step reaction sequence. Reaction of the latter with methyl p‐toluenesulfonate gave 1‐methylpyrazol‐3‐ones 2b‐d . Compounds 2b‐d were treated with aqueous nitric acid to give 4‐nitropyrazol‐3‐ones 3b‐d. Reduction of compounds 3b‐d by catalytic hydrogenation with Pd‐C afforded the 4‐amino compounds 4b, e, f. Using similar reaction conditions, nitropyrazole‐3‐ones derivatives 2c, d were reduced into aminopyrazole‐3‐ones 5e, f. 4‐Iodopyrazole‐3‐ones 7a, 7c and 8 were prepared from the corresponding pyrazol‐3‐ones 2a, 2c and 6 and iodine monochloride or sodium azide and iodine monochloride.     

Structural and Spectroscopic Characterization of a High‐Spin {FeNO}6 Complex with an Iron(IV)−NO− Electronic Structure

Although the interaction of low‐spin ferric complexes with nitric oxide has been well studied, examples of stable high‐spin ferric nitrosyls (such as those that could be expected to form at typical non‐heme iron sites in biology) are extremely rare. Using the TMG₃tren co‐ligand, we have prepared a high‐spin ferric NO adduct ({FeNO}⁶ complex) via electrochemical or chemical oxidation of the corresponding high‐spin ferrous NO {FeNO}⁷ complex. The {FeNO}⁶ compound is characterized by UV/Visible and IR spectroelectrochemistry, Mössbauer and NMR spectroscopy, X‐ray crystallography, and DFT calculations. The data show that its electronic structure is best described as a high‐spin iron(IV) center bound to a triplet NO^? ligand with a very covalent iron?NO bond. This finding demonstrates that this high‐spin iron nitrosyl compound undergoes iron‐centered redox chemistry, leading to fundamentally different properties than corresponding low‐spin compounds, which undergo NO‐centered redox transformations.     

镁铁和镁铁铝催化剂氢还原过程的研究

以水滑石为前体 ,制备了镁铁和镁铁铝复合氧化物催化剂 ,运用原位穆斯堡尔谱研究了催化剂在H2 气氛中的还原行为。结果表明 :由于Mg、Al的加入和固溶体的形成 ,相对地稳定了FeO物相 ,阻碍了H2 对铁离子的还原 ,使得Fe2 进一步还原为金属Fe0 的能力减弱 ;在还原过程中催化剂首先生成含Fe2 的固溶体FeO MgO或FeO MgO Al2O3,然后再完全还原成金属Fe0。     

2‐Chloro‐3‐(dimethylamino)prop‐2‐enoyl Fluoride,a Stable Acyl Fluoride

The title compound is formed as a side‐product in the reaction of CF₃CCl₃ with Zn/DMF and dimethyl(thexyl)silyl chloride (=dimethyl(1,1,2‐trimethylpropyl)silyl chloride). The structure and the double‐bond configuration are deduced from its ¹³C‐NMR data. Its formation is discussed in terms of a Vilsmeier‐type formylation and a reductive elimination.     

Furopyridines. XXX. Synthesis and reaction of difuro[3,2-c:- 3′,2′-e]pyridine,a new tricyclic heterocycle

Difuro[3,2-c:3′,2′-e]pyridine 1 , a new tricyclic heteroaromatic, has been prepared for the first time. Bromination of 1 with molecular bromine gave 3-bromo 7 , 8-bromo 7′ and 3,8-dibromo derivative 8 ; nitration with fuming nitric acid yielded 2-nitro compound 9 , while nitration with a mixture of fuming nitric acid and sulfuric acid gave 2,7-dinitro derivative 10 ; formylation with n-butyllithium and dimethylformamide gave 2-formyl 11 , 7-formyl 11′ , and 2,7-diformyl compound 12. The N-oxide 14 of 1 afforded 4-cyano compound 15 by cyanation with trimethylsilyl cyanide, 4-chloro compound 16 by chlorination with phosphorus oxychloride, and 4-acetoxyl compound 17 by acetoxylation with acetic anhydride.     

On the reaction of 3,4‐dihydropyrimidones with nitric acid. Preparation and x‐ray structure analysis of a stable nitrolic acid

A series of substituted 3,4‐dihydro‐2‐pyrimidones (DHPMs) was reacted with nitric acid under different reaction conditions. Treatment of DHPMs with 50‐65% nitric acid at 0 °C led to the formation of the corresponding dehydrogenated 2‐pyrimidones in moderate to good yields. In contrast, reaction of one representative DHPM with 60% nitric acid at 50 °C led to an unusually stable nitrolic acid, involving a formal nitration, nitrosation, and dehydrogenation step. The molecular structure of this product was determined by X‐ray crystallographic analysis     

A Practical and General Base‐Catalyzed Carbonylation of Amines for the Synthesis of N‐Formamides

A highly practical and general base‐catalyzed carbonylation of amines to the corresponding N‐formamides has been realized. Cheap inorganic bases, including Group IA and IIA metal hydroxides, alkoxides, carbonates, and phosphates, were effective catalysts for the transformation. In the presence of 10–40 mol % of KOH or K₂CO₃, various amines were converted into the corresponding N‐formamides in good‐to‐excellent yields using CO as the formylation reagents.     

Thermal analysis of RDX with contaminants

Many investigations and researches studied the reaction ability between high explosive RDX and RDX with other chemicals. However, accidents still occur and operating problems exist among the RDX manufacturing process. This study utilized inherent safety concepts and DSC thermal analysis to assess the incompatible reaction hazards of RDX during usage, handling, storage, transporting and manufacturing. This assessment includes thermal curve observations and kinetic evaluations. A decomposition mechanism of the incompatible reaction is proposed. Among all the contaminants evaluated in this study, the existence of ferrous chloride tetrahydrate, ferric chloride hexahydrate and nitric acid shifted the main endothermic and exothermic reactions of RDX. These contaminants further advanced the exothermic temperature onset average by about 53, 46 and 61°C, respectively. The summarized results suggest that ferric oxide, ferrous chloride tetrahydrate, ferric chloride hexahydrate, acetone solution and nitric acid can influence the reaction and thermokinetic properties of RDX. These chemicals could induce potential hazards by causing temperature control instability, heating and cooling systems failure, and produce an unexpected secondary explosion. According to the conclusions of this study, potential incompatible RDX hazards during usage and manufacturing could be avoided.     

A density functional theory study on diazotization and nitration of 3,5‐diamino‐1,2,4‐triazole

The reaction mechanism, thermodynamic and kinetic properties for diazotization and nitration of 3,5‐diamino‐1,2,4‐triazole were studied by a density functional theory. The geometries of the reactants, transition states, and intermediates were optimized at the B3LYP/6‐31G (d, p) level. Vibrational analysis was carried out to confirm the transition state structures, and the intrinsic reaction coordinate (IRC) method was used to explore the minimum energy path. The single‐point energies of all stagnation points were further calculated at the B3LYP (MP2)/6‐311+G (2d, p) level. The statistical thermodynamic method and Eyring transition state theory with Wigner correction were used to study the thermodynamic and kinetic characters of all reactions within 0–25°C. Two reaction channels are computed, including the diazotization and nitration of 3‐NH₂ or 5‐NH₂, and there are six steps in each channel. The reaction rate in each step is increased with temperature. The last step in each channel is the slowest step. The first, second, and fifth steps are exothermic reactions, and are favored at lower temperature in the thermodynamics. © 2010 Wiley Periodicals, Inc. Int J Quantum Chem, 2011