Heterocyclic complexes, substitution with

Diamino-substituted complexes of type 37 were first obtained by Fischer et al. [12] in two steps via the 1,2-addition-elimination product 34 from di-methylamine and 35 (Scheme 6). The (3-aminoallenylidene)chromium complexes 36, which can be prepared either from 33 [47,48] or directly from 35 [33], can also be transformed to l,3-bis(dialkylamino)-substituted complexes of type 37 (e.g., R2=z Pr) by treatment with dimethylamine in excellent yields [33]. Although the complex 37 is accessible by further reaction of the complex 34 with dimethylamine, and 34 itself stems from the reaction of 35 with dimethylamine, the direct transformation of 33 to 37 could not be achieved [12]. In spite of this, heterocyclic carbene complexes with two nitrogens were obtained by reactions of alkynylcarbene complexes 35 with hydrazine [49] and 1,3-diamines [50]. 

The high levels of enantioselectivity obtained in the asymmetric catalytic carbomagnesa-tion reactions (Tables 6.1 and 6.2) imply an organized (ebthi)Zr—alkene complex interaction with the heterocyclic alkene substrates. When chiral unsaturated pyrans or furans are employed, the resident center of asymmetry may induce differential rates of reaction, such that after -50 % conversion one enantiomer of the chiral alkene can be recovered in high enantiomeric purity. As an example, molecular models indicate that with a 2-substituted pyran, as shown in Fig. 6.2, the mode of addition labeled as I should be significantly favored over II or III, where unfavorable steric interactions between the (ebthi)Zr complex and the olefmic substrate would lead to significant catalyst—substrate complex destabilization. 

More than 25 different substituted urea herbicides are currently commercially available [30, 173]. The most important are phenylureas and Cycluron, which has the aromatic nucleus replaced by a saturated hydrocarbon moiety. Benzthiazuron and Methabenzthiazuron are more recent selective herbiddes of the class, with the aromatic moiety replaced by a heterocyclic ring system. With the exception of Fenuron, substituted ureas (i.e., Diuron, Fluometuron, Fig. 10, Table 3) exhibit low water solubilities, which decrease with increasing molecular volume of the compound. The majority of the phenylureas have relatively low vapor pressures and are, therefore, not very volatile. These compounds show electron-donor properties and thus they are able to form charge transfer complexes by interaction with suitable electron acceptor molecules. Hydrolysis, acylation, and alkylation reactions are also possible with these compounds. 

The low selectivity affects the synthetic interest of homolytic arylation from two points of view. The first concerns the position of substitution generally all the free positions are substituted, giving very complex mixtures of isomers. Thus, for example, quinoline gives all the seven possible isomers in appreciable amounts.This is in contrast to all the homolytic substitutions described in the previous sections, which lead to exclusive attack at the 2- and 4-positions. The other aspect concerns the conversions of the heterocyclic compounds, which are always very low, usually lower than 1%. If the conversions are high, the mixture of the reaction products becomes much more complex. Thus with quinoline it can be easily foreseen from the partial rate factors (Table IX) that not only all the possible 21 diphenylquinoline isomers, but also... 

Two independent papers have reported the synthesis of nitrogen-heterocycle complexes of the type [RhCl3(py-X)3] (py-X = 3-Etpy, 3-CNpy, 4-Etpy, or 4-CNpy) and rr(ans-[RhY2L4] (Y = Cl or Br L = several substituted pyridines, isoquinoline, pyrimidine, pyrazole, thiazole, and substituted imidazoles). All the compounds were prepared catalytically by boiling RhCl3.3H20 with ethanolic solutions of L. It is interesting that 2-substituted... 

Substituted pyrazolin-5-one heterocycles (187) have been coupled (Scheme 90) with a diazotized styrene-divinylbenzene copolymer (188) for purposes of forming a metal com-plexing resin (73MI11104). Resin (189) exhibited varying degrees of complexing ability with Cu +, Ni, Co, Mg2+ and Zn2+ ions. Selectivity was controlled primarily by the size of the R and R substituents. When R = Me and R = Pr1, for example, the resin exhibited a predominant selectivity for Cu2+ ion. 

In a nice illustration of the impact of metal coordination upon the reactivity of phospholes, a methodology for the functionalization of these heterocycles in the /3-position has been described (see also Scheme 22) <2001JOM105>. Here, coordination of both the P-lone pair and the cyclic diene system was undertaken. The resulting multimetallic complex 79 was treated with lithium diisopropylamide (LDA) to afford the lithium salt 350 (Scheme 118). This readily undergoes nucleophilic substitution with a variety of electrophiles to afford the corresponding substituted phosphole complexes 351-353. The free phospholes can be isolated following decomplexation with cerium(iv) ammonium nitrate (CAN). 

In contrast to CHEC-II(1996) where only rings which have relatively strong cr-bonds between adjacent atoms were reviewed, syntheses of heterocyclic complexes are also be described in this chapter. The chemistry of such chelates or coordination compounds is very interesting as the carbon-metal bond is labile and subject to various reactions such as insertion, protonation, or substitution. However, even though the synthesis of these intramolecular complexes is described in Section 4.19.9, their physical properties are not reported in this chapter. As the cyclic complex is in equilibrium with its open-chain form, the structural properties of such compounds may not be indicative of the heterocycle ring at all. 

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