Ionic state of tetrahedral

Imidate salts hydrolysis, 118-144 syn and anti, 120 isomerization, 142 B-lactam, 142 Iminium salts, 211-221 Imino-ethers, 147 lodolactonization, 169 Ionic state of tetrahedral intermediates, 65, 105-106, 119 Ionophore A-23187, 13 Isochromane-3-one, 70 Isocyanate, 300 Isonitrile, 296... 

The ionic state of the hemi-orthoamide tetrahedral intermediate must also be considered (9-12). In acidic medium, the intermediate will exist in... 

The ionic state of the hemi-orthoamide tetrahedral intermediate must also be considered (9-12). In acidic medium, the intermediate will exist in the protonated form T, in slightly basic medium (near the pKa of T°, pH = 10), it will exist as a mixture of T° and T-, and in basic medium (pH > 11), it will exist as T. ... 

Since 1971, he has developed a new stereoelectronic theory in which the precise conformation of the tetrahedral intermediate plays a major role. In other words, the stereochemistry and the ionic state of the tetrahedral intermediate, the orientation of nonbonded electron pairs, and the relative energy barriers for cleavage and for molecular rotation are the key parameters in the stereoelectronically controlled cleavage of the tetrahedral intermediate formed in the hydrolysis of an ester or an amide. He postulated that the precise conformation of the tetrahedral intermediate is transmitted into the product of the reaction and that the specific decomposition of such an inter-... 

The pentahalides of phosphorus, PX, in the gas phase exhibit varying tendencies to dissociate into trihaUde and halogen. InstabiUty increases with increasing ionic radius of the halogen. The pentafluoride appears to be thermally stable. Dissociation of the pentachloride, a few percent at 100°C and 101.3 kPa (1 atm), is essentially completed at 300°C (36). The pentabromide is partially dissociated in the Hquid state and totally dissociated above ca 35°C (39). Pentaiodide does not exist. The molecules of PF and PCl in the vapor phase are trigonal bipyramids. In the crystalline state, both pentachloride and pentabromide have ionic stmctures, ie, [PClJ IPClg] and [PBr4]" PBrJ , respectively. The PX" 4 cations are tetrahedral and the PX anion is octahedral (36,37). 

In the following, we start by assuming purely ionic structures. In spinel the oxide ions form a cubic closest-packing. Two-thirds of the metal ions occupy octahedral interstices, the rest tetrahedral ones. In a normal spinel the A ions are found in the tetrahedral interstices and the M ions in the octahedral interstices we express this by the subscripts T and O, for example Mgr[Al2](904. Since tetrahedral holes are smaller than octahedral holes, the A ions should be smaller than the M ions. Remarkably, this condition is not fulfilled in many spinels, and just as remarkable is the occurrence of inverse spinels which have half of the M ions occupying tetrahedral sites and the other half occupying octahedral sites while the A ions occupy the remaining octahedral sites. Table 17.3 summarizes these facts and also includes a classification according to the oxidation states of the metal ions. 

Characterization of Substituted Boron. We used solid state -B NMR and X-ray diffraction data to distinguish occluded borates from boron substituted into the zeolite framework. When an element replaces aluminum or silicon in a zeolite structure, the local coordination environment changes to accommodate the new ion. Since B + is a much smaller ion than Al "1", the unit cell axes contract when boron replaces aluminum in the framework. The ionic radii of trivalent B and A1 in a tetrahedral environment are 0.25 and 0.53, respectively (1). The magnitude of the contraction is dependent upon the level of substitution (17). 

From the discussion of Chapter I, it follows that metallic conduction is to be associated with partially filled bands of collective-electron states. Since the s-p bands of an ionic compound are either full or empty, metallic conduction implies partially filled d bands, and collective d electrons imply Rtt < Rc(n,d). From the requirement Rtt < Rc(n4) it is apparent that the metallic conduction in ionic compounds must be restricted either to transition element compounds in which the anions are relatively small or to compounds with a cation/anion ratio > 1. Also Rc(n,d) decreases, for a given n, with increasing atomic number, that is with increasing nuclear charge, and the presence of eQ electrons increases the effective size of an octahedral cation (627) (see Fig. 66) and similarly UQ electrons the size of a tetrahedral cation. It follows that If the cation/anion ratio < 1, MO d electrons are more probable in ionic compounds with octahedral-site cations if the cations contain three or less d electrons MO d electrons are more probable in ionic compounds with tetrahedral-site cations if the cations contain two or less d electrons. 

Silicon and aluminum, of course, are not unique in their ability to form tetrahedrally coordinated oxide networks. The element phosphorus, at the right of silicon in the periodic table, frequently assumes tetrahedral coordination with oxygen. With phosphorus in the +5 oxidation state as phosphate, aluminum phosphate possesses many structural similarities to silica 1) A1P0 is isoelectronic with S120 . 2) The average of the ionic radii of... 

Let us look first for transition-metal compounds that arc truly covalent in the sense of tetrahedral structures and two-electron bonds, which we di.scu.sscd earlier. There are only a few examples. NbN and TaN both form in the wurtzite structure. We presume that bond orbitals of sp hybrids must be present to stabilize the structure this requires three electrons from each transition-metal ion. Both ions are found in column D5 of the Solid State Table, so we anticipate that the remaining two electrons would form a multiplet (as in the ground stale of Ti " ). Thus the effects of the d state are simply added onto an otherwise simple covalent system, just as they were added to a simple ionic system in the monoxides. MnS, MnSe, and MnTe also form a wurtzite structure and presumably may be understood in just the same way. This class of compounds is apparently too small to have been studied extensively. 

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