Amine-catalyzed systems

Carboxylic nitrile liquid and solid elastomers are used to prepare elastomer-modified epoxy liquid and solid resins when it is desirable to have the modifier in the epoxy portion of the system. This is effected through alkyl-hydroxy esterification reactions. This is covered in the literature for uncatalyzed liquid resins (9), for tert-amine catalyzed systems (10), for tert-phosphine catalyzed systems (11), for low molecular weight solid resins advanced from the liquid state (12) and for liquid and solid resins where an additional rubber vulcanization step is carried out in addition to the alkylhydroxy ester adducting step (13). Such adduct preparations offer formulation stability with a wide range of hardener types amines, anhydrides, catalytic, Lewis acids/bases. 

Akzo Process. Akzo Zout Chemie has developed a route to vinyl chloride and soda ash from salt usiag an amine—solvent system catalyzed by a copper—iodide mixture (13). This procedure theoretically requires half the energy of the conventional Solvay processes. 

The 1-azirine ring also undergoes a number of reactions in which the heterocycle plays the role of the nucleophile. Although the basicity of the nitrogen atom in the azirine ring is much lower than in simple aliphatic amines, this system can still function as a nucleophilic reagent. One example of this involves the acid-catalyzed hydrolysis of 1-azirines to a-aminoketones (200) which represents a well-established reaction. In fact, in many reactions of 1-azirines where acid catalysis is used, formation of a-aminoketones is difficult to avoid (67JA44S6). 

The number of reactions that fit into this second class are manifold. Some typical examples are the amine-catalyzed reactions of 2,4-dinitrochlorobenzene with n-butylamine in chloroform (k"/k = 2.59 l.mole-1)23, with allylamine in chloroform (k"jk — 4.60 l.mole-1)24 and with allylamine in ethanol (k"fk =0.36 l.mole-1)25 and the amine-catalyzed reaction of p-nitrofluorobenzene with piperidine in polar solvents (k"/k < 3.2 l.mole-1)26. A typical example of a strongly catalyzed system is the reaction of 2,4-dinitrophenyl phenyl ether with piperidine in 60 % dioxan-40 % water27. 

Hydroaminomethylation of alkenes occurred to give both n- and /. so aliphatic amines catalyzed by [Rh(cod)Cl]2 and [Ir(cod)Cl]2 with TPPTS in aqueous NH3 with CO/H2 in an autoclave. The ratio of n-and /.soprimary amines ranged from 96 4 to 84 16.178 The catalytic hydroaminomethylation of long-chain alkenes with dimethylamine can be catalyzed by a water-soluble rhodium-phosphine complex, RhCl(CO) (Tppts)2 [TPPTS P(m-C6H4S03Na)3], in an aqueous-organic two-phase system in the presence of the cationic surfactant cetyltrimethy-lammonium bromide (CTAB) (Eq. 3.43). The addition of the cationic surfactant CTAB accelerated the reaction due to the micelle effect.179... 

In this particular system, 4-nitrobenzaldehyde dimethyl acetal is deprotected by the acid catalyst, followed by the addition of methyl vinyl ketone (MVK) in an amine-catalyzed Baylis-Hillman reaction to give the product (Scheme 5.14). A yield of 65% for the final product was observed when the catalysts described in Scheme 5.13 were used, compared with no observed yield for the reaction with their soluble analogs. 

Among the CH oxidations, a most impressive case, for example, concerns the quantitative TFD oxidation of cyclohexane to cyclohexanone at —22° C in only 18 min (equation 26) There exists no other chemical oxidant, even metal-catalyzed systems, that may compete with this astounding oxidative reactivity of TFD. Whether the oxidation of an amine to a hydroxylamine involves the direct insertion of an oxygen atom into the N—H bond is mechanistically still uncertain, since alternatively (more probably the case on... 

Milstein has demonstrated a reaction of primary alcohols with amines, catalyzed by the ruthenium (Ru)-pincer type system 13 to afford an amide with the generation of hydrogen gas [18]. The reaction as shown in Scheme 14.3 was found to be... 

The dimeric [Ru(CO)o(OCOCH3) (pip)]2 complex (2) may be used at the appropriate ruthenium molarities to reproduce exactly the uptake plots observed with the polymeric catalyst. Solution IR measurements in regions of maximum activity for both 1- and 2-catalyzed systems showed the presence of the amine dimers which could be readily precipitated at any stage of the catalytic carbonylation by adding water. 

The results show that a number of ruthenium carbonyl complexes are effective for the catalytic carbonylation of secondary cyclic amines at mild conditions. Exclusive formation of N-formylamines occurs, and no isocyanates or coupling products such as ureas or oxamides have been detected. Noncyclic secondary and primary amines and pyridine (a tertiary amine) are not effectively carbonylated. There appears to be a general increase in the reactivity of the amines with increasing basicity (20) pyrrolidine (pKa at 25°C = 11.27 > piperidine (11.12) > hexa-methyleneimine (11.07) > morpholine (8.39). Brackman (13) has stressed the importance of high basicity and the stereochemistry of the amines showing high reactivity in copper-catalyzed systems. The latter factor manifests itself in the reluctance of the amines to occupy more than two coordination sites on the cupric ion. In some of the hydridocar-bonyl systems, low activity must also result in part from the low catalyst solubility (Table I). 

Various alkane oxidations are catalyzed by iron complexes. Such reactions are important in view of the action of non-heme iron enzymes, such as methane monooxygenase, in hydrocarbon oxidations in biological systems. For example, the oxo-bridged complex [Fe2(TPA)2(ju,-0)(ju.-0Ac)]3+ [TPA = tris(2-pyridylmethyl)-amine] catalyzes the oxidation of cyclohexane with Bu OOH. Related complexes with an Fein2(/i-0)(/i-0Ac)2 core oxidize cyclohexane or adamantane to give a mixture of alcohols and ketones.159 Less well defined systems, e.g., FeCl3-6H20/ aldehyde/AcOH/02 are similarly active.160... 

Among the first reports was the investigation of an iron-catalyzed oxidation system in 1997. ESI-MS was used to characterize the intermediate [Fe "-TPA(OOH)]2 in the stereospecific hydroxylation of alkanes by hydrogen peroxide (TPA, tris(2-pyridyl-methyl)amine) [35]. It is unique among oxidation reactions studied by ESI-MS in that all other reports address manganese- or vanadium-catalyzed systems. 

Studies undertaken in connection with the amine-catalyzed asymmetric alkene osmylation have recently clarified the peculiar mechanism of the hexacyanoferrate/CO2 mediated osmium re-oxidation in biphasic conditions36. Reversal of the osmate oxidation/hydrolysis sequence with respect to the previously described R3NO-mediated conditions was noted with this system. Thus, the monodiolate(amine) osmium(VI) ester 9 appears to be first hydrolyzed, releasing the diol and the amine ligand to the organic phase, and the resulting [0s02(0H)4]2 into the aqueous phase. 

Poly (oxy-2,6-dimethyl-1,4-phenylene) (poly (phen-ylene oxide), PPO) is widely used as a high-performance engineering plastic, since the polymer has excellent chemical and physical properties, e.g., a high Tg (ca. 210 °C) and mechanical toughness. PPO was first prepared from 2,6-dimethylphenol monomer using a copper/amine catalyst system.25 The HRP-catalyzed polymerization of 2,6-dimethylphenol gave the polymer consisting of exclusively oxy-l,4-phe-nylene units.26... 

In Nolte and Drenth s nickel catalyzed system, the polymerization was believed to be initiated by a nucleophilic attack by the alcohol used as a solvent or the halide on the starting complex on the coordinated isocyanides. Successful asymmetric polymerization was achieved using a dicationic tetrakis(isocyanide)nickel(II) complex 46 with enantiopure primary amines, which served as a chiral nucleophile in the initial step (Scheme 35) [58, 59]. In a typical experiment, a catalyst prepared from (f-BuNC)4Ni(II)(C104)2 (46a) (1 mol%) and an optically active amine (1 mol%), was used for polymerization of isocyanides with, or without a solvent, such as n-hexane, in... 

In order to broaden the scope of the amine-catalyzed Michael addition, Yamaguchi examined the system of amine and alkali metal salt [2]. Although amine did not promote the addition of malonate to enones, the LiCl04-Et3N catalyst turned out to be effective. Optically active amines, however, gave racemic adducts. As an extension, the (S)-proline rubidium salt, (S)-21, was developed, which possessed a cation and an amine moiety in the same molecule [2, 22]. The catalyst (S)-21 in chloroform promoted the asymmetric addition of malonate to a wide range of enones and enals as exemplified by the reaction of... 

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