1197-19-9Relevant articles and documents
Synthesis of Triazidochlorosilane (TACS). A NovelSilicon Mediated one pot Conversion of Aldehyde to Nitriles
Elmorsy, Saad S.,El-Ahi, Abdel-Aziz S.,Soliman, Hanan,Amer, Fathy A.
, p. 2639 - 2640 (1995)
Synthesis, structure elucidation of triazidochlorosilane (TACS) and a novel conversion of aldehydes to nitriles in one pot reaction on treatment with TACS (SiCl4-NaN3 in Situ) reagent in acetonitrile are described.
Laser flash photolysis study of the photoinduced oxidation of 4-(dimethylamino)benzonitrile (DMABN)
Leresche, Frank,Ludvíková, Lucie,Heger, Dominik,Klán, Petr,Von Gunten, Urs,Canonica, Silvio
, p. 534 - 545 (2019)
Aromatic amines are aquatic contaminants for which phototransformation in surface waters can be induced by excited triplet states of dissolved organic matter (3DOM*). The first reaction step is assumed to consist of a one-electron oxidation process of the amine to produce its radical cation. In this paper, we present laser flash photolysis investigations aimed at characterizing the photoinduced, aqueous phase one-electron oxidation of 4-(dimethylamino)benzonitrile (DMABN) as a representative of this contaminant class. The production of the radical cation of DMABN (DMABN+) after direct photoexcitation of DMABN at 266 nm was confirmed in accord with previous experimental results. Moreover, DMABN+ was shown to be produced from the reactions of several excited triplet photosensitizers (carbonyl compounds) with DMABN. Second-order rate constants for the quenching of the excited triplet states by DMABN were determined to fall in the range of 3 × 107-5 × 109 M?1 s?1, and their variation was interpreted in terms of electron transfer theory using a Rehm-Weller relationship. The decay kinetics of DMABN+ in the presence of oxygen was dominated by a second-order component attributed to its reaction with the superoxide radical anion (O2?). The first-order rate constant for the transformation of DMABN+ leading to photodegradation of DMABN was estimated not to exceed ≈5 × 103 s?1
Kinetics and Mechanisms of Oxygen Transfer in the Reaction of p-Cyano-N,N-Dimethylaniline N-Oxide with Metalloporphyrin Salts. 3. Catalysis by iron(III) Chloride
Dicken, C. Michael,Woon, T. C.,Bruice, Thomas C.
, p. 1636 - 1643 (1986)
Decomposition of p-cyano-N,N-dimethylaniline N-oxide (NO) catalyzed by iron(III) chloride ((Cl8TPP)FeIIICl) yields as products p-cyano-N,N-dimethylaniline (DA), p-cyano-N-methylaniline (MA), and formaldehyde (CH2Cl2 solvent, 25 deg C, N2 atmosphere).Intermediate in the reaction are mono and bis NO complexes (Cl8TPP(Cl)FeIIINO and Cl8TPP(NO)FeIIINO, respectively).Oxygen transfer from the complexed NO species to the iron porphyrin is rate-limiting and provides the higher valent iron(IV) salts (IVO>+. and IVO>+.) and DA.The observed kinetics for reactions involving 10-100 turnovers of catalyst dictate that the catalyst is saturated in the formation of Cl8TPP(Cl)FeIIINO and that formation of Cl8TPP(NO)FeIIINO is unfavorable.The two iron(IV)-oxo porphyrin ?-cation radical species are converted back to the iron(III) porphyrin catalytic moieties by oxidation of DA -> MA + CH2O and oxidation of CH2O.Addition of 2,4,6-tri-tert-butylphenol (TBPH), 2,3-dimethyl-2-butene (TME), and cyclohexene results in the formation of TBP. and the respective epoxides, thus inhibiting the oxidation of DA and CH2O.The kinetics of the overall reaction and formation of each product may be simulated by employing the reactions of Scheme II and eq l-r, and from the simulations, the rates and equilibria, leading to the formation of the two iron(IV)-oxo porphyrin ?-cation radical species may be determined as can minimal rate constants for the oxidations of DA, CH2O, and TBPH and the epoxidation of TME and cyclohexene.The results obtained herein with the electron-deficient porphyrin, (Cl8TPP)Fe(III)Cl, are discussed and compared to those obtained previously when employing (TPP)FeIIICl as the catalyst.
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Ramakrishnan,Boyer
, p. 429 (1972)
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The Kinetics and Mechanisms of Oxygen Transfer in the Reaction of p-Cyano-N,N-dimethylaniline N-Oxide with Metalloporphyrin Salts. 4. Catalysis by meso-(Tetrakis(2,6-dimethylphenyl)porphinato)iron(III) Chloride
Woon, T. C.,Dicken, C. Michael,Bruice, Thomas C.
, p. 7990 - 7995 (1986)
meso-(Tetrakis(2,6-dimethylphenyl)porphinato)iron(III) chloride ((Me8TPP)Fe(III)Cl) is a catalyst for the conversion of p-cyano-N,N-dimethylaniline N-oxide (NO) to p-cyano-N,N-dimethylaniline (DA), p-cyano-N-methylaniline (MA), p-cyano-N-formyl-N-methylaniline (FA), p-cyanoaniline (A), N,N'-dimethyl-N,N'-bis(p-cyanophenyl)hydrazine (H), N,N'-bis(p-cyanophenyl)-N-methylmethylenediamine (MD), and CH2O.All evidence supports these reactions to occur by equilibrium ligation of NO to iron(III) porphyrin followed by rate-detrmining oxygen transfer to yields as intermediate products DA and the iron(IV)-oxo porphyrin ?-cation radical.Stepwise oxidation of DA by the higher valent iron-oxo porphyrin species is responsible for the formation of the other products (i.e., DA-->-->FA, DA-->MA-->A, 2MA-->MD, and 2MA-->H).The oxidation potentials of (Me8TPP)Fe(III)OCH3 are comparable to those of the unsubstituted meso-(tetraphenylporphinato)iron(III) methoxide ((TPP)Fe(III)OCH3).The following results are, therfore, not surprising: (i) The second-order rate constant (kakb/k-a) for reaction of (Me8TPP)Fe(III)Cl with NO is but 3.3-fold smaller than in the case of the reaction of NO with (TPP)Fe(III)Cl; (ii) the percentage yields of products (DA, 53percent; MA, 24percent; A, 3percent; FA, 8percent; H, 7percent; MD, 5percent) are comparable to when (TPP)Fe(III)Cl is employed; and (iii) oxidation and epoxydation of added substrates are not rate-determining.Of considerable interest is the finding that epoxidation reactions using NO with (Me8TPP)Fe(III)Cl occur in much higher yield (80percent to 100percent) than when (TPP)Fe(III)Cl is used as the catalyst.
Microwave activation in organic synthesis: Natural Indian clay, EPIC(R) EPZG(R) and EPZ10(R) as novel heterogenous catalysts for rapid synthesis of nitriles from aldoximes in absence of solvent
Bandgar,Sadavarte,Sabu
, p. 3409 - 3413 (1999)
The Conversion of aldoximes into nitriles was carried out in the absence of solvent under microwave irradiation using environmentally-friendly catalysts like natural kaolinitic clay, EPIC(R) EPZG(R) and EPZ10(R). Acceleration of reaction rate, simple work-up and formation of clean products are salient features of this method.
Nitrile Synthesis via Desulfonylative-Smiles Rearrangement
Abe, Masahiro,Nitta, Sayasa,Miura, Erina,Kimachi, Tetsutaro,Inamoto, Kiyofumi
, p. 4460 - 4467 (2022/03/15)
Herein, we designed a simple nitrile synthesis from N-[(2-nitrophenyl)sulfonyl]benzamides via base-promoted intramolecular nucleophilic aromatic substitution. The process features redox-neutral conditions as well as no requirement of toxic cyanide species and transition metals. Our process shows broad scope and various functional group compatibility, affording a variety of (hetero)aromatic nitriles in good to excellent yields.
CuO-catalyzed conversion of arylacetic acids into aromatic nitriles with K4Fe(CN)6 as the nitrogen source
Ren, Yun-Lai,Shen, Zhenpeng,Tian, Xinzhe,Xing, Ai-Ping,Zhao, Zhe
, (2020/10/26)
Readily available CuO was demonstrated to be effective as the catalyst for the conversion of arylacetic acids to aromatic nitriles with non-toxic and inexpensive K4Fe(CN)6 as the nitrogen source via the complete cleavage of the C[tbnd]N triple bond. The present method allowed a series of arylacetic acids including phenylacetic acids, naphthaleneacetic acids, 2-thiopheneacetic acid and 2-furanacetic acid to be converted into the targeted products in low to high yields.
Efficient nitriding reagent and application thereof
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Paragraph 0219-0222, (2021/03/31)
The invention discloses an efficient nitriding reagent and application thereof, wherein the nitriding reagent comprises nitrogen oxide, an active agent, a reducing agent and an organic solvent. By applying the nitriding reagent, nitrogen-containing compounds such as amide, nitrile and the like can be produced, and the method is simple in condition, low in waste discharge amount and simple in reaction equipment.
