Nitrogen bond number

Lipases are the enzymes for which a number of examples of a promiscuous activity have been reported. Thus, in addition to their original activity comprising hydrolysis of lipids and, generally, catalysis of the hydrolysis or formation of carboxylic esters [107], lipases have been found to catalyze not only the carbon-nitrogen bond hydrolysis/formation (in this case, acting as proteases) but also the carbon-carbon bond-forming reactions. The first example of a lipase-catalyzed Michael addition to 2-(trifluoromethyl)propenoic acid was described as early as in 1986 [108]. Michael addition of secondary amines to acrylonitrile is up to 100-fold faster in the presence of various preparations of the hpase from Candida antariica (CAL-B) than in the absence of a biocatalyst (Scheme 5.20) [109]. 

A number of ab initio molecular orbital calculations have been performed on acyclic and cyclic phosphazenes. These calculations point to a phosphorus-nitrogen bond with a large degree of charge separation and a small but essential contribution from phosphorus d-orbitals. 

Table 1 Calculation of some molecular-based descriptors for BOA, DIMBOA and MBOA. Physicochemical descriptor like logP (partition coefficient between octanol and water) constitutional descriptors like the number of a specified atoms or bonds (number of carbons, hydrogens, oxygens, nitrogens, single and aromatic bonds, the total number of atoms and bonds) and molecular weight quantum-mechanical descriptors like HOMO (Highest Occupied Molecular Orbital) and LUMO (Lowest Unoccupied Molecular Orbital).

Iodinated contrast agents with polyhydroxylated carbon side-chains contain a number of asymmetric carbon atoms yielding numerous optical isomers which relate to each other as enantiomers or diastereoisomers. Sterically hindered non-asymmetric carbon or nitrogen atoms might result in additional asymmetry centres while the partial double bond character of the acyl-carbon-nitrogen bond of amide functions can lead to cisitrans isomerism. Such isomers are labelled rotamers when heating in solution is able to modify their ratio. Isomerism of iodixanol has been described by Priebe et al. [122], Fossheim et al. [123] and by Molander et al. [115]. 

Dinitrogen Tetroxide.—The dimer of nitrogen dioxide is not very stable its enthalpy of formation from the monomer is 13.873 kcal/mole. The molecule is found in both the crystal (x-ray diffraction)29 and the gas (electron diffraction)80 to be planar, with orthorhombic symmetry. The N—N bond length reported for the crystal is 1.64 A. The value for the gas molecule, 1.75 A, is probably somewhat more accurate.81 This value is 0.28 A greater than the single-bond value found for hydrazine the bond number of the bond is accordingly about 0.34 (Equation 7-7). 

There is, of course, resonance of the double bonds between the alternative positions.) In the foregoing discussion of NO it was concluded that the occupancy of the nitrogen atom by the odd electron of the N 0 bond is about 65 percent. If the three-electron bond in NO2 is similar and the resonance for the two N02 molecules is unsynchronized, the odd electrons would have 42 percent simultaneous location on the nitrogen atoms, and hence the bond number 0.42 tvould be expected. This result agrees satisfactorily with the value 0.34 given by the bond length. 

Amide resonance is a powerful stabilizing force and gives rise to a number of structural effects. Unlike the pyramidal arrangement of bonds in ammonia and amines, the bonds to nitrogen in amides lie in the same plane. The carbon-nitrogen bond has considerable double-bond character and, at 135 pm, is substantially shorter than the normal 147-pm carbon-nitrogen single-bond distance observed in amines. 

Until recently, the synthesis of ionic/covalent nitrides was relatively unexplored except for the pioneering work of Juza on ternary lithium nitrides.11 However, within the last decade, several groups have begun to explore ternary nitride systems, many of which have relied on the inductive effect. The inductive effect is based on the donation of electron density from an electropositive element to an adjacent metal-nitrogen bond, thereby increasing the covalency and stability of that bond and of the nitride material itself. The success of this method is illustrated by the fact that almost all of the known ionic/covalent ternary nitrides contain electropositive elements. Only recently has a small number of transition metal ternary nitrides been synthesized in the absence of the inductive effect at moderate temperatures, by taking advantage of low temperature techniques, such as the ammonolysis of oxide precursors and metathesis reactions.6,12-17... 

Ambiguity may arise when more than one structure contributes. Then unshared pairs in one structure may become multiple bonds in another, so that the number of electron groups around a given atom is not the same in both structures. An example is methyl azide (19). The central nitrogen is clearly linear (two electron groups), but the nitrogen bonded to CH3 has three electron groups in... 

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