Demanding reaction

Diels-Alder reactions can be divided into normal electron demand and inverse electron demand additions. This distinction is based on the way the rate of the reaction responds to the introduction of electron withdrawing and electron donating substituents. Normal electron demand Diels-Alder reactions are promoted by electron donating substituents on the diene and electron withdrawii substituents on the dienophile. In contrast, inverse electron demand reactions are accelerated by electron withdrawing substituents on the diene and electron donating ones on the dienophile. There also exists an intermediate class, the neutral Diels-Alder reaction, that is accelerated by both electron withdrawing and donating substituents. 

At about the same time that the Birkeland-Eyde process was developed, the Frank-Caro cyanamide process was commercialized (14). In this process limestone is heated to produce lime, which then reacts with carbon in a highly energy-demanding reaction to give calcium carbide. Reaction with N2 gives calcium cyanamide [150-62-7] which hydrolyzes to ammonia and calcium carbonate (see Cyanamides). 

The normal electron-demand reaction is a HOMOdiene-LUMOdienophUeelectron-rich dienes and electron-deficient dienophiles (Scheme 4.2, left dotted line). The inverse electron-demand cycloaddition reaction is primarily controlled by a LUMOdiene HOMOdienophiie inter-... 

The two transition states in Figs 8.5 and 8.6 correspond in principle to a metal-catalyzed carho-Diels-Alder reaction under normal electron-demand reaction conditions and a hetero-Diels-Alder reaction with inverse electron-demand of an en-one with an alkene. The calculations by Houk et al. [6] indicated that with the basis set used there were no significant difference in the reaction course. 

The basic concept of activation in hetero-Diels-Alder reactions is to utilize the lone-pair electrons of the carbonyl and imine functionality for coordination to the Lewis acid. The coordination of the dienophile to the Lewis acid changes the FMOs of the dienophile and for the normal electron-demand reactions a decrease of the LUMO and HOMO energies is observed leading to a better interaction with... 

The inverse electron demand reactions of 2,4,6-tris(ethoxycarbonyl)-1,3,5-triazine and 5-aminopyrazoles to provide a one-step synthesis of pyrazolo[3,4-. 

These are examples of structure Insensitive (facile) (Reactions 1-4) and structure sensitive (demanding) reactions (Reactions 3-7). 

Terrier et al. have widely described Bfxs 4-nitro-substituted participating in a series of Diels-Alder processes. Bfx 4-nitro-substituted system could participate as diene, C = C - C = C system, or heterodiene, C = C - NO2 system, in an inverse electron demand reaction [62,63] or as dienophile, C = C or N = O systems, in a normal electron demand reaction [64-68]. Fxs have been reported as 1,3-dipole through the substructure C = - 0 reacting with... 

BINOL in conjunction with TiCl2(0-/-Pr)2 gives good enantioselectivity in a D-A reaction with a pyrone as the diene.116 This is a case of an inverse electron demand reaction and the catalysts would be complexed to the diene. 

F. Substituent Effects in Highly Electron-Demanding Reactions. .. 520... 

In considering quantitatively the response of these groups to high electron-demand there are certain caveats. In the first place it must be remembered that amino and related groups are liable to be protonated in the kind of media often used for studying electrophilic aromatic substitution. The observed substituent effect will then be that of the positive pole. Secondly, the straightforward application of the tr+ scale to electron-demanding reactions is not necessarily appropriate. It may well be that some form of multiparameter treatment is needed, perhaps the Yukawa-Tsuno equation (Section II.B). 

As a demanding reaction, it is very sensitive to the structural and compositional details of the anode materials. For this reason, research on anodes for O2 evolution calls for close characterization of electrocatalysts, especially from the point of view of materials chemistry and physics. 

Nitrones can be activated mainly in two different ways for the 1,3-dipolar cycloaddition with alkenes. In the reaction between a nitrone and an electron-dehcient alkene, such as an a,p-unsaturated carbonyl compound (a normal electron-demand reaction), it is primarily controlled by the interaction between HOMOnitrone-LUMOaikene (Scheme 12.64). By coordination of a Lewis acid (LA) catalyst to the a,p-unsaturated carbonyl compound, the LUMOaikene energy decreases and a better interaction with the nitrone can take place (16,17). 

Bosnich and co-workers (363) used the chiral titanocene-(OTf)2 complex 254 for the 1,3-dipolar cycloaddition between the cyclic nitrone 239a and the ketene acetal 226c for an inverse electron-demand reaction (Scheme 12.79). The reaction proceeded only in the presence of the catalyst, and a good cis/trans ratio of 8 92 was obtained using catalyst 254, although only 14% ee was observed for the major isomer. 

Aqueous hetero Diels-Alder reaction was first described by Grieco, who reported the use of water as solvent for cyclocondensations of iminium salts (Larsen and Grieco, 1985). Known as being a very energy demanding reaction, the retro Diels-Alder process is usually not considered as a competitive pathway in most Diels-Alder... 

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