Foundations of Chemistry. Philippa B. Cranwell

Foundations of Chemistry - Philippa B. Cranwell


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      As stated earlier, calcium is in Group 2. Therefore, to gain a full outer shell, it needs to lose two electrons. In doing this, it will have a 2+ charge.

      Fluorine is in Group 7. Therefore, to gain a full outer shell, it needs to gain one electron. By doing this, it has a negative charge. To balance the two electrons given up by calcium, there need to be two fluorine atoms present that can each take one electron.

Schematic illustration of the Lewis structure for calcium fluoride.

      2.1.4 Covalent bonding

      Covalent bonding occurs between two non‐metal atoms. In a covalent bond, each atom contributes one or more electrons to share with the other atom. The driving force behind covalent bonding is similar to that in ionic bonding: each element wants to achieve a full outer shell of electrons. In the case of covalent bonding, electrons are shared rather than lost or gained. The covalent bond itself is very strong; a large amount of energy is required to break a covalent bond.

      Covalent bonding occurs between non‐metals. A covalent bond is a shared pair of electrons.

      The symbol σ is the Greek letter sigma. A σ bond consists of a pair of electrons shared between two covalently bonded atoms.

Schematic illustrations of (a) the formation of a single bond in hydrogen, H2; (b) an alternative representation of a hydrogen molecule with a single bond; (c) a representation of the location of the electrons in a sigma bond.

      Although the electrons in the hydrogen atoms are shown as dots and crosses, all the electrons are identical.

Schematic illustrations of (a) the formation of a double bond in oxygen, O2; (b) an alternative representation of an oxygen molecule with a double bond.

      The symbol π is the Greek letter pi. A π bond consists of a pair of electrons located between two covalently bonded atoms in a plane at 90° to the bond axis.

      The oxygen atom has six outer electrons. The electron configuration is 1s22s22p4. An oxygen atom requires two additional electrons to fill its outer shell and attain a complete octet of electrons as in the atom neon, the closest noble gas. Thus, in the formation of an oxygen molecule, each oxygen atom shares two of its outer electrons with another oxygen atom. There is therefore a total of four electrons bonding the oxygen atoms together. When four electrons are shared between two atoms, a double bond is formed, which is represented by a double horizontal line between the atoms in the bond.

      In covalent bonding, the first two electrons to be shared form a sigma bond. If more than two electrons are shared, the electrons occupy pi bonds.

      Worked Example 2.4

      Draw a dot‐and‐cross diagram to show the bonding present in carbon dioxide, CO2.

       Solution

      Carbon dioxide contains two elements: carbon and oxygen. Both are non‐metals; therefore, the type of bonding between them will be covalent, i.e. shared pairs of electrons. Carbon has four electrons in its outer shell and therefore needs to gain another four electrons to fill its outer shell. Oxygen has six electrons, so it needs to gain two more electrons. In addition, the name carbon dioxide gives a hint about the structure, with the ‘di’ showing that there are two oxygen atoms.

      This information allows us to deduce that if carbon shares two electrons with each oxygen, each oxygen will have eight electrons in its outer shell and so will have a complete octet. Conversely, if oxygen shares two electrons each with carbon, carbon will have gained a share of four electrons in total, so it will also have a full outer shell. In the case of carbon dioxide, there are two pairs of electrons between each nucleus (a). Thus, there is a double bond between each carbon and oxygen atom. This is represented by a double line between the atoms (b).

Schematic illustration of a dot-and-cross diagram to show the bonding present in carbon dioxide.
Name and molecular formula Dot‐and‐cross diagram Display formula
Fluorine, F2 Schematic illustration of the dot and cross diagram of Fluorine. Schematic illustration of the display <hr><noindex><a href=Скачать книгу
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