Foundations of Chemistry. Philippa B. CranwellЧитать онлайн книгу.

bonded pairs. These shapes are called tetrahedral, pyramidal and, bent (or angular). Figure 2.16 shows examples of molecules that adopt each of the three shapes. When there are four single bonds to the central atom, e.g. in methane, the molecule adopts a tetrahedral shape (Figure 2.16a). When there are three single bonds to the central atom and one lone pair of electrons, e.g. in ammonia, NH₃, the molecule adopts a pyramidal shape (Figure 2.16b). When there are two bonds and two pairs of electrons around the central atom, e.g. water, H₂O, the molecule adopts a bent or angular shape (Figure 2.16c). The lone pairs have an impact on the bond angles between the bonded atoms and the central atoms because the lone pairs occupy more space than the bonding pairs. In a symmetrical tetrahedral molecule, the angle between each of the covalent bonds is 109.5°; in a pyramidal compound, the angle is 107°; and in a bent compound, it is 104.5°. This reflects the larger space that the lone pairs occupy, pushing the bonding electrons closer together; see Figure 2.16.

Schematic illustrations of (a) bonding angles in a tetrahedral bonding centre; (b) bonding angles in a pyramidal bonding centre; (c) bonding angles in a bent (or angular) bonding centre.

Figure 2.16 (a) Bonding angles in a tetrahedral bonding centre; (b) bonding angles in a pyramidal bonding centre; (c) bonding angles in a bent (or angular) bonding centre.

The rule of thumb for deciding the order of interactions between areas of electron density in a molecule is:

Lone pair–lone pair > lone pair–bonded pair > bonded pair–bonded pair

2.2.5 Five electron centres around the central atom: trigonal bipyramidal molecules

If there are five areas of electron density around the central atom, the molecule adopts a trigonal bipyramidal shape, as shown in Figure 2.17 for phosphorus pentachloride, PCl₅. The angle in the plane around the phosphorus atom between each of the equatorial bonds is 120°, and the angle between the equatorial bonds and the axial bonds is 90°.

Schematic illustrations of (a) bonding angles in a trigonal bipyramidal molecule; (b) phosphorus pentachloride, PCl5 superimposed into a trigonal bipyramid.

Figure 2.17 (a) Bonding angles in a trigonal bipyramidal molecule; (b) phosphorus pentachloride, PCl₅ superimposed into a trigonal bipyramid.

Box 2.2

You will come across the terms axial and equatorial throughout your studies in chemistry. An axial bond is one that runs vertically up and down along a single axis, whereas an equatorial bond is located horizontally across the page or in the equatorial plane of the molecule.

Schematic illustration of an axial bond that runs vertically up the page.

2.2.6 Six electron centres around the central atom: octahedral molecules

When there are six areas of electron density around the central atom or six single covalent bonds, the molecule adopts an octahedral shape. If all six bonded atoms are identical, the angle between each of the bonds is 90°, as this is the furthest apart that all six components can arrange themselves around the central atom. Figure 2.18 depicts the shape of the sulfur hexafluoride, SF₆ molecule: the six fluorine atoms arrange themselves as far apart as possible around the central sulfur atom. The reason for the name octahedral is that the shape made by the six bonds from a central atom has eight faces, which is an octahedron.

SF₆ is used extensively in insulating high‐voltage electrical transmittance cables and switching gear. It is now known to be the most potent greenhouse gas and is banned in all applications apart from in the electrical industry.

Schematic illustrations of (a) the bonding angles in an octahedral molecule; (b) sulfur hexafluoride, SF6 superimposed into an octahedron.

Figure 2.18 (a) Bonding angles in an octahedral molecule; (b) sulfur hexafluoride, SF₆ superimposed into an octahedron.

Summary

We have seen that when considering the arrangement of atoms in a covalently bonded molecule, a molecule can adopt seven basic shapes. These shapes are based on five different distributions of electron density around the central atom and are shown in Figure 2.19. Other combinations of bonded atoms and lone pairs can result in different shapes not included here: for example, the ammonium ion, NH₄⁺, has the same shape as a methane, CH₄ molecule as the nitrogen atom is surrounded by four N—H bonds which constitute four areas of electron density.

Schematic illustration of common shapes of simple covalent molecules.

Figure 2.19 Common shapes of simple covalent molecules.

Worked Example 2.5

Describe the bonding present in silane, SiH₄, and determine the shape of the molecule.

Solution

The first thing to determine is the number of areas of electron density around the central silicon atom. Both silicon and hydrogen are non‐metals; therefore, the bonding is covalent. A dot‐and‐cross diagram can be used to describe the bonding. There are four bonds from the silicon atom to the hydrogen atoms, and no lone pairs; thus there are four areas of electron density, so the shape of silane is tetrahedral. The bonding and shape of the molecule are exactly analogous to methane, CH₄, as both carbon and silicon are in the same group of the periodic table.

Schematic illustration of the bonding present in silane.

Worked Example 2.6

Describe the bonding present in hydrogen sulfide, H₂S, and determine the shape of the molecule.

Solution

Sulfur, the central atom, is in Group 6 (Group 16), so it has six valence electrons and needs to gain two more to complete the octet. This is achieved by bonding to hydrogen. There are four areas of electron density around sulfur consisting of two single bonds and two lone pairs of electrons. The four areas of electron density arrange themselves as far apart as possible and form a tetrahedral shape. However, because two of these areas of electron density are lone pairs, the actual shape of the molecule appears to be bent (i.e. we can't ‘see’ the lone

Скачать книгу