Category: quinoxaline

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: 221012-82-4, is researched, Molecular C38H34N2O4P2, about Asymmetric hydrogenation of quinolines with recyclable and air-stable iridium catalyst systems, the main research direction is quinoline asym hydrogenation recyclable iridium catalyst; tetrahydroquinoline alkyl asym synthesis.Category: quinoxaline.

The iridium complex-catalyzed asym. hydrogenation of quinolines in a poly(ethylene glycol) di-Me ether (DMPEG)/hexane biphasic system was studied. Catalysts with C2-sym. ligands such as Xyl-P-Phos, Cl-MeO-BIPHEP, SYNPHOS, and DifluorPhos are highly effective for this type of reaction. Most of the catalysts tested can be retained in DMPEG (Mn = 500), and the asym. hydrogenation of various quinoline substrates can be carried out in DMPEG/hexane biphasic system with up to 92% ee. The catalysts and the products can be separated via simple phase separation, and the reactivity/stereoselectivity of the catalysts can be retained for at least three reaction cycles.

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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.Hasell, T.; Little, M. A.; Chong, S. Y.; Schmidtmann, M.; Briggs, M. E.; Santolini, V.; Jelfs, K. E.; Cooper, A. I. researched the compound: (S)-Propane-1,2-diamine dihydrochloride( cas:19777-66-3 ).Synthetic Route of C3H12Cl2N2.They published the article 《Chirality as a tool for function in porous organic cages》 about this compound( cas:19777-66-3 ) in Nanoscale. Keywords: organic cage compound diastereoselective preparation crystal structure chiral recognition. We’ll tell you more about this compound (cas:19777-66-3).

The investigation of chiral analogs of cages that were previously studied as racemates was described. It was shown that chiral cages could be produced directly from chiral precursors or by separating racemic cages by co-crystallization with a second chiral cage, opening up a route to producing chiral cages from achiral precursors. These chiral cages can be cocrystd. in a modular, ‘isoreticular’ fashion, thus modifying porosity, although some chiral pairings required a specific solvent to direct the crystal into the desired packing mode. Certain cages were shown to interconvert chirality in solution, and the steric factors governing this behavior were explored both by experiment and by computational modeling.

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Easwaran, K. R. K.; Srinivasan, Ramaswami published the article 《Nuclear magnetic resonance study of some paramagnetic hydrated fluorides》. Keywords: ZINC FLUORIDE NMR; NMR PARAMAGNETIC FLUORIDE; NICKEL FLUORIDE NMR; PARAMAGNETIC FLUORIDE NMR; IRON FLUORIDE NMR; COBALT FLUORIDE NMR; FLUORIDE PARAMAGNETIC NMR.They researched the compound: Nickel(ii)fluoridetetrahydrate( cas:13940-83-5 ).Recommanded Product: 13940-83-5. 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:13940-83-5) here.

N.M.R. studies of proton and F nuclei are reported in a series of compounds MF2.4H2O, where M is Fe, Co, Ni, and Zn. The spectra of the 3 paramagnetic salts were different from those of the diamagnetic ZnF2.4H2O. Proton resonance studies of the paramagnetic members have shown marked changes in line width on cooling from room temperature to 90°K. The 19F resonance in the paramagnetic salts in polycrystalline from have shown large shifts which were temperature dependent. The results are discussed in terms of the hyperfine fields owing to the unpaired electrons of the paramagnetic ions.

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Most of the compounds have physiologically active properties, and their biological properties are often attributed to the heteroatoms contained in their molecules, and most of these heteroatoms also appear in cyclic structures. A Journal, Article, Research Support, Non-U.S. Gov’t, Organic Letters called Kinetic Resolution of 2-Substituted 2,3-Dihydro-4-pyridones by Palladium-Catalyzed Asymmetric Allylic Alkylation: Catalytic Asymmetric Total Synthesis of Indolizidine (-)-209I, Author is Lei, Bai-Lin; Zhang, Qing-Song; Yu, Wei-Hua; Ding, Qiu-Ping; Ding, Chang-Hua; Hou, Xue-Long, which mentions a compound: 221012-82-4, SMILESS is COC(C=C1P(C2=CC=CC=C2)C3=CC=CC=C3)=NC(OC)=C1C4=C(OC)N=C(OC)C=C4P(C5=CC=CC=C5)C6=CC=CC=C6, Molecular C38H34N2O4P2, Category: quinoxaline.

The kinetic resolution of 2-substituted-2,3-dihydro-4-pyridones was realized via a Pd-catalyzed allylic substitution reaction using a com. available (S)-P-Phos as a ligand, affording optically active dihydropyridones and C-allylated dihydropyridones in high yields and good enantioselectivities with the S-factor up to 43. With this protocol, a catalytic asym. total synthesis of indolizidine (-)-209I (I) was realized for the first time.

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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 Ru-catalyzed highly enantioselective hydrogenation of β-alkyl-substituted β-(acylamino)acrylates, published in 2003-03-21, which mentions a compound: 221012-82-4, mainly applied to beta amino acid enantioselective preparation; bipyridyldiphosphine ruthenium complex enantioselective hydrogenation beta amino acrylate; enantioselective hydrogenation beta amino acrylate bipyridyldiphosphine ruthenium rhodium complex; rhodium bipyridyldiphosphine complex enantioselective hydrogenation Z beta aminoacrylate; ruthenium bipyridyldiphosphine complex enantioselective hydrogenation E beta aminoacrylate, Safety of (R)-2,2′,6,6′-Tetramethoxy-4,4′-bis(diphenylphosphino)-3,3′-bipyridine.

β-Alkyl-substituted (E)-β-(acylamino)-acrylates R1C(AcNH):CHCO2R2 (R1 = Me, Et, EtCH2, Me2CH, Me3C; R2 = Me, Et) undergo enantioselective hydrogenation in the presence of the nonracemic bipyridyldiphosphine I (R = 3,5-Me2C6H3) and [RuCl2(benzene)]2 to provide β-aminoesters R1CH(NHAc)CH2CO2R2 in up to 99.7% ee. (Z)-β-(acylamino)-acrylates R1C(AcNH):CHCO2R2 (R1 = Me, Et, EtCH2, Me2CH, Me3C; R2 = Me, Et) undergo enantioselective hydrogenation in the presence of nonracemic bipyridyldiphosphine I (R = 3,5-Me2C6H3) and Rh(COD)2BF4 to provide β-aminoesters R1CH(NHAc)CH2CO2R2 in 57-82% ee. Hydrogenation does not occur in the presence of ruthenium or rhodium complexes of I (R = Ph, 4-MeC6H4, 3,5-Me2C6H3) in aprotic solvents; methanol is found to be the optimal solvent. Decreasing the hydrogen pressure increases the enantioselectivity marginally, with 4 atm. of hydrogen pressure being optimal. Ruthenium complexes of I give higher enantioselectivities for hydrogenation of (E)-β-aminoacrylates than the corresponding rhodium complexes; for the hydrogenation of (Z)-β-aminoacrylates, rhodium complexes of I give higher enantioselectivities than the corresponding ruthenium complexes. Variations in the electronic and steric properties of the dipyridylphosphine ligand, variation of the transition metal used, and variations in the enamine stereochem. influence the rate and enantioselectivity of the hydrogenation of β-(acylamino)acrylates.

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SDS of cas: 217192-22-8. 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: (4-(Pyridin-4-yl)phenyl)methanol, is researched, Molecular C12H11NO, CAS is 217192-22-8, about A Switchable Catalyst Duo for Acyl Transfer Proximity Catalysis and Regulation of Substrate Selectivity.

Enzymes are encoded with a gamut of information to catalyze a highly selective transformation by selecting the proper reactants from an intricate mixture of constituents. Mimicking biol. machinery, two switchable catalysts with differently sized cavities and allosteric control are conceived that allow complementary size-selective acyl transfer in an on/off manner by modulating the effective local concentration of the substrates. Selective activation of one of two catalysts in a mixture of reactants of similar reactivity enabled upregulation of the desired product.

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Reference of Nickel(ii)fluoridetetrahydrate. Aromatic compounds can be divided into two categories: single heterocycles and fused heterocycles. Compound: Nickel(ii)fluoridetetrahydrate, is researched, Molecular F2H8NiO4, CAS is 13940-83-5, about Preparation of high-purity nickel compound from Ni-containing waste materials. Author is Gu, Heng; Li, Xingying; Zhu, Jianchun; Zhou, Jinyun.

The process conditions for the preparation of high-purity Ni compounds (NiSO4.6H2O, NiF2.4H2O, Ni(Ac)2.4H2O, and NiO) from Ni-containing waste carbonate by H2SO4 leaching were studied, and a technol. process was proposed. The principle for the purification and extraction of Ni solution in the system of H2SO4 was discussed with phase diagram. The recovery of Ni was 92%, and the quality of the product met the national standard

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The reaction of an aromatic heterocycle with a proton is called a protonation. One of articles about this theory is 《Synthesis and study of N-oxides of heterocyclic compounds. I. N-Oxides of derivatives of morphine, tetra-hydroisoquinoline, and quinoline》. Authors are Khaletskii, A. M.; Pesin, V. G.; Tsin, Chshou.The article about the compound:8-Hydroxyquinoline 1-oxidecas:1127-45-3,SMILESS:OC1=CC=CC2=CC=C[N+]([O-])=C12).Product Details of 1127-45-3. Through the article, more information about this compound (cas:1127-45-3) is conveyed.

cf. Ochiai, C.A. 48, 3359i. Heating 8.4 g. codeine with 45 ml. 3% H2O2 at 50-60° gave after evaporation 8 g. codeine N-oxide, m. 206-8° (H2O); HCl salt, m. 214-17° (EtOH). To 5 g. dihydrohydroxycodeinone-HCl was added 10 ml. 10% NaOH yielding 93% dihydrohydroxycodeinone, m. 213-16°, which with 3% H2O2 as above gave 46.2% dihydrohydroxycodeinone N-oxide, decompose 152-3°, which gives a red color with Ac2O; picrate, m. 190-2°; HCl salt, m. 167-8°. The oxide treated with SO2 in warm EtOH gave 62.5% C18H23O8NS, decompose 169-70°, which was evidently an isomer of dihydrohydroxycodeinone sulfate; with BaCl2 solution it readily gave BaSO4; hydrolysis with 10% NaOH gave the original dihydrohydroxycodeinone, m. 207-9° (sulfate, m. 138-9°). Salsolidine (3 g.) in 20 ml. Me2CO and 30 ml. H2O treated with 2.5 ml. 30% H2O2 after several days at room temperature gave 15.48% N-hydroxysalsolidine, m. 100-1° (aqueous EtOH), which reduced Fehling and Tollens reagents. Similarly, N-methylsalsolidine gave N-methylsalsolidine N-oxide picrate, m. 133-4° (aqueous EtOH); HCl salt analog, decompose 162-3°. Oxidation of salsoline with 3% H2O2 in AcOH or with BzO2H in CHCl3 either gave no reaction or failed to yield any definite products. N-Methylsalsoline with aqueous H2O2 at room temperature in 3 days gave N-methylsalsoline N-oxide, m. 183° (EtOH); HCl salt, m. 186°. Oxidation of 8-hydroxyquinoline in CHCl3 with BzO2H with cooling gave yellow 8-hydroxyquinoline N-oxide, m. 137-8° (H2O); the same formed on oxidation with 30% H2O2 in AcOH-Ac2O at 40-5° in 3 hrs., but with 30% H2O2-AcOH in 2 hrs. only the starting material was recovered. 8-Hydroxyquinoline N-oxide treated with alc. KOH and Etl at reflux gave 8-ethoxyquinoline N-oxide, isolated as picrate, m. 135-8°; the same formed on treatment of 8-ethoxyquinoline with AcOH-Ac2O-30% H2O2 at 45-50°; HCl salt, m. 158°; free oxide, m. 61-2°. Similarly 2-phenylquinoline-4-carboxylic acid and AcOH-H2O2 gave 76% N-oxide, m. 244°, and 15% benzoylanthranilic acid, m. 170-2°. Oxidation of 2-phenylquinoline-4-carboxylic acid with BzO2H in CHCl3 in 2 days gave no evident reaction, the same being true of oxidation with 25% H2O2 in EtOH-Me2CO at 50°. Reduction of 2-phenylquinoline-4-carboxylic acid N-oxide with Na hydrosulfite in aqueous EtOH gave the original 2-phenylquinoline-4-carboxylic acid, m. 205-7°.

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The chemical properties of alicyclic heterocycles are similar to those of the corresponding chain compounds. Compound: 8-Hydroxyquinoline 1-oxide, is researched, Molecular C9H7NO2, CAS is 1127-45-3, about Palladium-Catalyzed Alkenylation of Quinoline-N-oxides via C-H Activation under External-Oxidant-Free Conditions, the main research direction is palladium catalyst stereoselective regioselective alkenylation quinoline oxide.Formula: C9H7NO2.

The direct cross-coupling of quinoline-N-oxides with olefin derivatives has been realized using palladium acetate as the catalyst in the absence of external ligand and oxidant to give the corresponding 2-alkenylated quinolines and 1-alkenylated isoquinolines chemo- and regioselectively in 27-95% yield. The catalytic process is proposed to proceed via direct C-H bond activation of the quinoline-N-oxide with Pd(OAc)2 followed by Heck coupling with the olefin. The resultant N-oxide of the alkenylated quinoline can oxidize the reduced Pd(0) to regenerate the Pd(II) active species and simultaneously release the 2-alkenylated quinoline without using any external oxidants and reductants.

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The three-dimensional configuration of the ester heterocycle is basically the same as that of the carbocycle. Compound: 8-Hydroxyquinoline 1-oxide(SMILESS: OC1=CC=CC2=CC=C[N+]([O-])=C12,cas:1127-45-3) is researched.Formula: C9H7NO2. The article 《Molecular and crystal structure of 8-hydroxyquinoline N-oxide》 in relation to this compound, is published in Acta Crystallographica, Section B: Structural Crystallography and Crystal Chemistry. Let’s take a look at the latest research on this compound (cas:1127-45-3).

The structure of 8-hydroxyquinoline N-oxide was determined from diffractometer data by a direct method. The compound crystallizes in the monoclinic system with space group P21/c. The cell data are: a 12.1364(4), b 4.9211(2), c 13.1384(4) Å, β 109.26(1)°, d.(calculated)=1.449, d.(exptl.)=1.46, Z=4. The structure was solved by a direct method. 1528 reflections were used in a full-matrix least-squares refinement. R was reduced to a final value of 0.053. Bond lengths between non-H atoms have estimated standard derivations (e.s.d.’s) between 0.002 and 0.003 Å. The e.s.d.’s of the various bond angles (non-H atoms) range from 0.01 to 0.02°. Distances and angles involving the H atoms have e.s.d.’s of 0.02 Å and 1°, resp. The 2 C-N distances of the quinoline ring are unusually long, and the quinoline moiety is surprisingly similar to naphthalene in terms of bond distances and angles. The inductive effect of the N-O group may in part be responsible for the C-N lengthenings. The hydroxyl H atom is bonded to the dative O atom via a short intramol. H bond. The direct relation between the N-O dative bond distance and the strength of a H bond to the dative O atom appears to be substantiated in this study.

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