Trigonal orbitals

R I /y - lone pair in sp2 orbital trigonal planar t/fo trigonal planar... 

In ethene the situation is rather different here, each carbon atom has one 2s and two 2p orbitals hybridised to form three sp single-pear orbitals which are trigonal planar (shown shaded in each half of Figure 2. JO). The remaining 2p orbital is not hybridised,... 

The element before carbon in Period 2, boron, has one electron less than carbon, and forms many covalent compounds of type BX3 where X is a monovalent atom or group. In these, the boron uses three sp hybrid orbitals to form three trigonal planar bonds, like carbon in ethene, but the unhybridised 2p orbital is vacant, i.e. it contains no electrons. In the nitrogen atom (one more electron than carbon) one orbital must contain two electrons—the lone pair hence sp hybridisation will give four tetrahedral orbitals, one containing this lone pair. Oxygen similarly hybridised will have two orbitals occupied by lone pairs, and fluorine, three. Hence the hydrides of the elements from carbon to fluorine have the structures... 

Physical Properties. Sulfur tetrafluoride has the stmcture of a distorted trigonal bipyramid, the sulfur having hybrid sp d orbitals and an unshared electron pair (93). The FSF bond angles have been found to be 101° and 187°, and the bond distances 0.1646 and 0.1545 nm (94). 

The triaLkoxy(aryloxy)boranes are typically monomeric, soluble in most organic solvents, and dissolve in water with hydrolysis to form boric acid and the corresponding alcohol and phenol. Although the rate of hydrolysis is usually very fast, it is dependent on the bulk of the alkyl or aryl substituent groups bonded to the boron atom. Secondary and tertiary alkyl esters are generally more stable than the primary alkyl esters. The boron atom in these compounds is in a trigonal coplanar state with bond hybridization. A vacantp orbital exists along the threefold axis perpendicular to the BO plane. 

A similar situation obtains in the aminoboranes where one or more of the substituents on B is an R2N group (R = alkyl, aryl, H), e.g. Me2N-BMc2. Reference to Fig. 6.22 indicates the possibility of some p, interaction between the lone pair on N and the vacant orbital on trigonal B. This is frequently indicated as... 

Calculations for trigonal bipyramidal ML4(NO) systems with axial NO-like [Ir(NO)(PPh3)3H+] give a d orbital sequence of xz,yz < x2 — y2, xy < z2 so that in such an IrNO 8 system, the z2 orbital is unoccupied not only does bending not produce any stabilization but in fact dxz, dyz — 7r back-bonding is lost, favouring a linear Ir—N—O bond. 

Every water molecule in a crystalline hydrate has, as its nearest neighbours [579], two proton acceptors and at least one electron acceptor. Where only a single electron acceptor is present, co-ordination of the H20 molecule is approximately planar trigonal, and, when two are present, tetrahedral co-ordination is adopted. Large deviations from these configurations seldom occur. Classification [579—582] of the water molecules in hydrates, on the basis of co-ordination of the lone pair orbitals, has been discussed further [579,581] and modified [580] (see Fig. 9 and Table 9). For example, the water in CuS04 5 H20 is located in three different environments two H20 molecules are in Class 1, type D two are in Class 1, type J, and the remaining one is in Class 2, type E. 

We use different hybridization schemes to describe other arrangements of electron pairs (Fig. 3.16). For example, to explain a trigonal planar electron arrangement, like that in BF, and each carbon atom in ethene, we mix one s-orbital with two /7-orbitals and so produce three sp2 hybrid orbitals ... 

Answer Three cr-bonds formed from F2/7c-orbitals and B2s/r hybrids in a trigonal planar arrangement]... 

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