Category: 1195-58-0

Heterocyclic compounds can be divided into two categories: alicyclic heterocycles and aromatic heterocycles. Compounds whose heterocycles in the molecular skeleton cannot reflect aromaticity are called alicyclic heterocyclic compounds. Compound: 1195-58-0, is researched, Molecular C7H3N3, about In Situ Generation of Electrolyte inside Pyridine-Based Covalent Triazine Frameworks for Direct Supercapacitor Integration, the main research direction is electrolyte pyridine covalent triazine framework supercapacitor; covalent triazine frameworks; cyclotrimerization; nitrogen heterocycles; supercapacitors; waste prevention.Recommanded Product: Pyridine-3,5-dicarbonitrile.

The synthesis of porous electrode materials is often linked with the generation of waste that results from extensive purification steps and low mass yield. In contrast to porous carbons, covalent triazine frameworks (CTFs) display modular properties on a mol. basis through appropriate choice of the monomer. Herein, the synthesis of a new pyridine-based CTF material is showcased. The porosity and nitrogen-doping are tuned by a careful choice of the reaction temperature An in-depth structural characterization by using Ar physisorption, XPS, and Raman spectroscopy was conducted to give a rational explanation of the material properties. Without any purification, the samples were applied as sym. supercapacitors and showed a specific capacitance of 141 F g-1. Residual ZnCl2, which acted formerly as the porogen, was used directly as the electrolyte salt. Upon the addition of water, ZnCl2 was dissolved to form the aqueous electrolyte in situ. Thereby, extensive and time-consuming washing steps could be circumvented.

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Wu, Ting Kai published the article 《Proton chemical shifts of the symmetrically disubstituted pyridines》. Keywords: CHEM SHIFTS PROTON; PYRIDINES SYM DISUBSTITUTED; SHIELDING MECHANISM; PROTON CHEM SHIFTS.They researched the compound: Pyridine-3,5-dicarbonitrile( cas:1195-58-0 ).Synthetic Route of C7H3N3. Aromatic heterocyclic compounds can be divided into two categories: single heterocyclic and fused heterocyclic. In addition, there is a lot of other information about this compound (cas:1195-58-0) here.

3,5-Disubstituted pyridines (R2C5H3N, where R = CN, Br, Cl, and Me) and 2,6-disubstituted pyridines (R’2C5H3N, where R’ = NH2, OMe, Me, Cl, Br, and COMe) were studied by N.M.R. spectra to determine the substituent effects on the chem. shifts for further insight into the nature of the shielding mechanisms in the pyridine π-electron system. The additive substituent effects on the proton chem. shifts of the sym. disubstituted pyridines provide further supporting evidence for the interpretation of Wu and Dailey [J. Chem. Phys. 41, 3307(1964)] that the shielding mechanisms in the pyridines are virtually the same as those in benzenes.

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The reaction of an aromatic heterocycle with a proton is called a protonation. One of articles about this theory is 《Dihydropyridines. V. Formation of the isomeric 1,2- and 1,4-dihydro derivatives in the reaction of methylmagnesinm iodide with 3,5-dicyanopyridine and 3,5-dicyano-2-methylpyridine》. Authors are Kuthan, J.; Janeckova, E.; Havel, M..The article about the compound:Pyridine-3,5-dicarbonitrilecas:1195-58-0,SMILESS:N#CC1=CC(C#N)=CN=C1).Synthetic Route of C7H3N3. Through the article, more information about this compound (cas:1195-58-0) is conveyed.

cf. CA 58, 5626a. MeMgI adds to 3,5-dicyanopyridine (I) to give 3,5-dicyano-2-methyl-1,2-dihydropyridine (II) and 3,5-dicyano-4-methyl-1,4-dihydropyridine (III). Similarly, 3,5-dicyano-2-methylpyridine (IV) forms 3,5-dicyano-2,6-dimethyl-1,2-dihydropyridine (V) and 3,5-dicyano-2,4-dimethyl-1,4-dihydropyridine (VI), resp. Nicotinoyl chloride-HCl (from 500 g. nicotinoic acid and 1400 ml. SOCl2) refluxed 35 hrs. with 500 ml. Br, the mixture evaporated on a steam bath, the residue dissolved in 1 l. absolute EtOH, and the solution heated 30 min. on a steam bath gave 81% HBr salt of Et 5-bromonicotinate, m. 147-7.5° (EtOH), from which 80% Et 5-bromonicotinate (VII), b0.5 86-92°, m. 42°, was obtained by treatment with Na2CO3. VII (50 g.) stirred with 30 g. CuCN in 50 ml. HCONMe2 2 hrs. at 160-75°, the mixt evaporated in vacuo, and the residue shaken with 500 ml. concentrated NH4OH and extracted successively with 800 ml. C6H6 and 200 ml. Et2O gave after evaporation 45% Et 5-cyanonicotinate (VIII), b16 143-5°, m. 89-90° (petr. ether). VIII (50 g.) in 1 l. absolute EtOH saturated with NH3 kept 7 days at room temperature gave 72% 5-cyanonicotinamide (IX), m. 220-1° (H2O, EtOH). A mixture of 14 g. IX and 40 ml. anhydrous C5H5N treated over 15 min. with 9 ml. POCl3, stirred 8 hrs., decomposed with ice, alkalized with NH4OH, and extracted with CHCl3 gave 64% I, m. 113-13.5° (dilute EtOH), sublimed 80-90°/10 mm. K salt of 2-hydroxy-3,5-dicyano-6-methylpyridine (6.07 g.) and 7 g. PCl5 treated with 10 ml. POCl3, and the mixture refluxed 30 min., evaporated in vacuo, decomposed with ice, and extracted with C6H6 gave 35% 3,5-dicyano-2-chloro-6-methylpyridine, m. 143-3.5°, which gave IV, m. 76-7°, on catalytic hydrogenation. Reaction of 1.04 g. I in 70 ml. Et2O with MeMgI (from 0.8 g. Mg, 2 ml. MeI, and 30 ml. Et2O) followed by chromatography on Al2O3 (activity II) gave 512 mg. yellow II, m. 114-15° (C6H6, dilute EtOH), and 240 mg. yellowish III, m. 180.5-81° (dilute EtOH). Similarly, 670 mg. IV with MeMgI (from 0.72 g. Mg, 1.9 ml. MeI, and 25 ml. Et2O) afforded 405 mg. yellow V, m. 152-3° (dilute MeOH), and 138 mg. yellowish VI, m. 129.5-30.5°. Dehydrogenation of II, III, V, and VI by heating with equal amounts 30% Pd-C 20 min. at 200-5° gave IV, 3,5-dicyano-4-methylpyridine, m. 84.5-85°, 3,5-dicyano-2,6-dimethylpyridine, m. 118-18.5°, and 3,5-dicyano-2,4-dimethylpyridine, m. 115-15.5°, resp. Ultraviolet and infrared data for II, III, V, and VI, and of some of the intermediates, are given.

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The chemical properties of alicyclic heterocycles are similar to those of the corresponding chain compounds. Compound: Pyridine-3,5-dicarbonitrile, is researched, Molecular C7H3N3, CAS is 1195-58-0, about Optimizing Open Iron Sites in Metal-Organic Frameworks for Ethane Oxidation: A First-Principles Study, the main research direction is metal organic framework open iron site ethane oxidation; DFT; catalyst screening; ethane; ethanol; metal−organic frameworks; nitrous oxide.HPLC of Formula: 1195-58-0.

Activation of the C-H bonds in ethane to form ethanol is a highly desirable, yet challenging, reaction. Metal-organic frameworks (MOFs) with open Fe sites are promising candidates for catalyzing this reaction. One advantage of MOFs is their modular construction from inorganic nodes and organic linkers, allowing for flexible design and detailed control of properties. In this work, we studied a series of single-metal atom Fe model systems with ligands that are commonly used as MOF linkers and tried to understand how one can design an optimal Fe catalyst. We found linear relationships between the binding enthalpy of oxygen to the Fe sites and common descriptors for catalytic reactions, such as the Fe 3d energy levels in different reaction intermediates. We further analyzed the three highest-barrier steps in the ethane oxidation cycle (including desorption of the product) with the Fe 3d energy levels. Volcano relationships are revealed with peaks toward higher Fe 3d energy and stronger electron-donating group functionalization of linkers. Furthermore, we found that the Fe 3d energy levels pos. correlate with the electron-donating strength of functional groups on the linkers. Finally, we validated our hypotheses on larger models of MOF-74 iron sites. Compared with MOF-74, functionalizing the MOF-74 linkers with NH2 groups lowers the enthalpic barrier for the most endothermic step in the reaction cycle. Our findings provide insight for catalyst optimization and point out directions for future exptl. efforts.

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Pratt, J. Richard; Massey, W. Dale; Pinkerton, Frank H.; Thames, Shelby F. published the article 《Organosilicon compounds. XX. Synthesis of aromatic diamines via trimethylsilyl-protecting aniline intermediates》. Keywords: protective group trimethylsilyl aniline; silyl trimethyl protective aniline; diamine aromatic; amine di aromatic; dinitrile lithioaniline; nitrile di lithioaniline; aniline lithio silyl keto; imine lithio; carbonyl compound diamino; keto di diamine; silicon diamine.They researched the compound: Pyridine-3,5-dicarbonitrile( cas:1195-58-0 ).Category: alcohols-buliding-blocks. Aromatic heterocyclic compounds can be divided into two categories: single heterocyclic and fused heterocyclic. In addition, there is a lot of other information about this compound (cas:1195-58-0) here.

A synthetic approach utilizing a Me3Si protecting group was used to produce Si and diketo containing diamines. Thus, the halogen-metal interchange of N,N-bis(trimethylsilyl)bromoanilines with BuLi in ether produced Li derivatives, which were treated with dichloro silanes or dinitriles to afford the N,N-bis(trimethylsilyl)silicon containing dianilines or the corresponding lithioimines, resp. Hydrolysis removed the trimethylsilyl protecting groups and converted the lithioimines to the carbonyl compounds to afford the free diamines.

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The reaction of an aromatic heterocycle with a proton is called a protonation. One of articles about this theory is 《Dihydropyridines. VII. Reactions of symmetrically alkylated 3,5-dicyanopyridines with sodium borohydride》. Authors are Kuthan, J.; Janeckova, E..The article about the compound:Pyridine-3,5-dicarbonitrilecas:1195-58-0,SMILESS:N#CC1=CC(C#N)=CN=C1).SDS of cas: 1195-58-0. Through the article, more information about this compound (cas:1195-58-0) is conveyed.

cf. ibid. 1495; CA 60, 6817d. NaBH4 reduction of 3,5-dicyanopyridines I-VI gave 3,5-dicyano-1,2- and 1,4-dihydropyridines VII-XVII. I and LiAlH4 gave a mixture of VII and VIII which was separated by chromatography. Two procedures were used in the reduction of I-VI: Method A. EtOH (0.2 ml.) was added to a mixture of 38 mg. NaBH4 and 0.001 mole ground I-VI, and the precipitated product washed with 2.5 ml. cold H2O. Method B. NaBH4 (150 mg.) was added to a mixture of 0.002 mole I-VI and 5 ml. EtOH, the solution diluted with H2O to ∼80 ml. after several hrs., and the precipitated filtered off (starting compound, method, product, % yield, and m.p. given): I, B, VIII, 62, 205-6° (dilute EtOH); I, A, VII, 188-9° (Me2CO-cyclohexane) (VIII was also obtained); II, A, IX, 50, 214-15° (dilute EtOH); III, A, X + XI (92:8), 44, 154-72° (mixture); IV, B, XII, 89, 232-3° (MeOH); V, B, XIV + XV (71:29), 69, 138-69° (mixture); VI, -, XVI + XVII (86:14), 77, 108-22° (mixture). Similar results were obtained by reduction of I-IV with LiAlH4. Oxidation of 1.73 g. 3,5-dicyano-2-methyl-4-ethyl-1,2-dihydropyridine in 70 ml. EtOH with Ag2O from 7 g. AgNO3 gave 91% 3,5-dicyano-2-methyl-4-ethylpyridine (XVIII), m. 68-8.5°, sublimed 55-60°/0.4 mm. Treatment of 1.28 g. XVIII with MeMgI prepared from 750 mg. Mg and 1.9 ml. MeI gave 61% XVII, m. 101-2° (dilute acetone), which was oxidized with MnO2 to VI, m. 70-1°.

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So far, in addition to halogen atoms, other non-metallic atoms can become part of the aromatic heterocycle, and the target ring system is still aromatic.Hartman, Tomas; Sturala, Jiri; Cibulka, Radek researched the compound: Pyridine-3,5-dicarbonitrile( cas:1195-58-0 ).Synthetic Route of C7H3N3.They published the article 《Two-Phase Oxidations with Aqueous Hydrogen Peroxide Catalyzed by Amphiphilic Pyridinium and Diazinium Salts》 about this compound( cas:1195-58-0 ) in Advanced Synthesis & Catalysis. Keywords: green chem oxidation amphiphilic pyridinium diazinium salt catalyst; oxidation aqueous hydrogen peroxide amphiphilic pyridinium diazinium salt catalyst. We’ll tell you more about this compound (cas:1195-58-0).

Amphiphilic pyridinium and diazinium salts were shown to be effective catalysts in two-phase (water/chloroform or water/dichloromethane) sulfoxidations and N-oxidations with hydrogen peroxide under mild conditions. This unprecedented oxidation method utilizes covalent bonding of hydrogen peroxide to a simple pyridinium or diazinium nucleus to increase the lipophilicity of the hydroperoxide species and to subsequently activate it for oxidations in a non-polar medium. The catalytic efficiency was found to depend on the type of heteroarenium core and on the lipophilicity of the catalyst. Five series of heteroarenium catalysts were prepared and investigated: 1-Alkyl-3,5-dicyanopyridinium, 1-alkyl-3,5-dinitropyridinium, 1-alkyl-3-cyanopyrazinium, 1-alkyl-4-cyanopyrimidinium and 1-alkyl-4-(trifluoromethyl)pyrimidinium triflates (alkyl=butyl, hexyl, octyl, decyl, dodecyl and hexadecyl). Among them, the 1-octyl-3,5-dinitropyridinium and 1-decyl-4-(trifluoromethyl)pyrimidinium triflates were found to be superior catalysts, showing the best stability and the highest catalytic activity, achieving acceleration by a factor of 350 relative to the non-catalyzed reaction. In contrast to other organocatalytic two-phase oxidations that use hydrogen peroxide, the presented method is characterized by high chemoselectivity and low catalyst loading (5 mol%) and with the reactions being performed under mild conditions, i.e., at 25° using diluted hydrogen peroxide and a non-basic aqueous phase. The catalysts have simple structures and are readily available from com. materials. Practical applications are demonstrated via the oxidation of several types of sulfides and amines.

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Reference of Pyridine-3,5-dicarbonitrile. The protonation of heteroatoms in aromatic heterocycles can be divided into two categories: lone pairs of electrons are in the aromatic ring conjugated system; and lone pairs of electrons do not participate. Compound: Pyridine-3,5-dicarbonitrile, is researched, Molecular C7H3N3, CAS is 1195-58-0, about Photochemistry of matrix-isolated 5-cyano-2H-pyran-2-one (δ-cyano-α-pyrone) and cyanocyclobuta-1,3-diene. Author is Menke, Jessica L.; McMahon, Robert J..

Matrix-isolation photochem. (λ > 299 nm; Ar, 10 K) of 5-cyano-2H-pyran-2-one (5, δ-cyano-α-pyrone) shows complete conversion to a mixture of several ring-opened ketene isomers (6) and a ring-closed Dewar lactone (7), as detected by IR spectroscopy. Subsequent irradiation (λ > 200 nm) causes decarboxylation of the Dewar lactone (7) to produce cyanocyclobuta-1,3-diene (8). Continued irradiation (λ > 200 nm) results in the photodecomposition of cyanocyclobuta-1,3-diene (8) to cyanoacetylene and acetylene. 4-Cyanopyridine (10) was explored as an alternative photochem. precursor to cyanocyclobuta-1,3-diene (8). It was found, however, that 10 does not exhibit observable photochem. under our irradiation conditions.

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Quality Control of Pyridine-3,5-dicarbonitrile. So far, in addition to halogen atoms, other non-metallic atoms can become part of the aromatic heterocycle, and the target ring system is still aromatic. Compound: Pyridine-3,5-dicarbonitrile, is researched, Molecular C7H3N3, CAS is 1195-58-0, about Substituted thieno[2,3-d]pyrimidines as adenosine A2A receptor antagonists.

A novel series of benzyl substituted thieno[2,3-d]pyrimidines, e.g. I, were identified as potent A2A receptor antagonists. Several five- and six-membered heterocyclic replacements for the optimized methylfuran were explored. Select compounds effectively reverse catalepsy in mice when dosed orally.

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In organic chemistry, atoms other than carbon and hydrogen are generally referred to as heteroatoms. The most common heteroatoms are nitrogen, oxygen and sulfur. Now I present to you an article called The reduction of pyridine derivatives with lithium aluminum hydride, published in 1953, which mentions a compound: 1195-58-0, mainly applied to , Safety of Pyridine-3,5-dicarbonitrile.

When pyridine derivatives (I) with CO2Et or CN groups at the 3- and 5-positions are treated with LiAlH4 (II) the ring system is attacked first; when the 2-, 4-, and 6-positions are substituted, the functional group are reduced. The reductions are carried out by adding a large excess of II in ether to the I in absolute ether with stirring and ice-cooling, treating the mixture with saturated NH4Cl solution, and evaporating the washed ether solution Reduction of 5 g. di-Et 2,6-lutidine-3,5-dicarboxylate in 50 cc. ether with 780 mg. II in 40 cc. ether gives 40% Et 3-hydroxymethyl-2,6-lutidine-5-carboxylate, m. 100-1°; when the mixture is refluxed 2 hrs. 65% 3,5-bis(hydroxymethyl)-2,6-lutidine, m. 141-2°, is obtained. Reduction of di-Me dinicotinate gives 50% di-Me 1,4-dihydrodinicotinate, m. 150-60°, λmaximum 220, 375 mμ (MeOH). Reduction of di-Me 2-methyl-dinicotinate also gives a dihydro derivative, b0.02 115-20°, yellow needles, m. 126°, λmaximum 220, 375 mμ (MeOH). Reduction of 10 g. 2-chloropyridine (III) with 1 g. II at 0° gives unchanged III. Reduction of 1 g. Et picolinate gives 2-pyridine methanol (picrate m. 159°). Reduction of Et 2-pyridyl-acetate gives 2-pyridineëthanol, b15 120° (picrate, m. 120°). Refluxing 50 g. dinicotinic acid with 150 cc. SOCl2 15 hrs. and treating the acid chloride with NH4OH give 26 g. diamide, m. 302°, which, warmed in 130 cc. C5H5N with 19 cc. POCl3 3 hrs at 60°, yields 15 g. dinitrile (IV), m. 113° after sublimation at 70°/1 mm. Reduction of 1 g. IV in 20 cc. ether with 300 mg. II in 10 cc. ether gives 1,4-dihydrodinicotinonitrile, yellow crystals, m. 197°, λmaximum 360 mμ (MeOH). Similar reduction of 0.43 g. 2,6-lutidine-3,5-dicarbonitrile gives the 1,4-dihydro derivative, yellow crystals, m. 225°, λmaximum 362.5 mμ (MeOH). Catalytic hydrogenation of 0.5 g. IV in 20 cc. MeOH 3 hrs. with 50 mg. PtO2, 0.5 g., gives a dihydro derivative with λmax. 360 mμ which reduces neutral AgNO3. Adding (0.5 hr.) 6.5 g. II in 300 cc. ether to 46 g. Me nicotinate in 300 cc. ether at 0°, decomposing the mixture with NH4Cl, and distilling the residue of the ether extract give 31.3 g. 3-pyridine methanol, b0.1 110° (picrate, m. 158-60°). The difference in the behavior of the pyridine esters and nitriles toward II is explained as resulting from the different polarization of the pyridine rings in these compounds

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