Bonding Models
Bonding Models
- Models simplify complex systems and allow us to predict and test theories
- As we have seen, chemical bonding broadly falls into three types: ionic, covalent and metallic
- The bonding types can be used to explain chemical and physical properties of substances
- However, like all models, there are limitations and inaccuracies that arise from oversimplification
- For example, take a substance like aluminium chloride, AlCl3. The compound consists of a metal and non-metal, so the traditional bonding approach would be to predict it has ionic bonding and the associated properties of an ionic compound such as high melting point and boiling point
- Aluminium chloride actually melts at 192oC, so it does not behave like an ionic compound
- The fact we know polar covalent bonds exist arise provides evidence that bonding type is not something that can be easily compartmentalised
- Bonding is best thought of as a continuum of the three different bonding types like the area of an equilateral triangle
A bonding model
Chemical bonding is a continuum of ionic, covalent and metallic bonding
- The location of an element or compound in the bonding triangle is determined by the electronegativity values of the elements present
- The bonding triangle is anchored by two axes, electronegativity difference on the y-axis and average electronegativity on the x-axis
- The symbol for electronegativity is the Greek letter (chi) χ, pronounced 'ky' as in 'sky'
- The average electronegativity of two elements, A and B would be:
format('truetype')%3Bfont-weight%3Anormal%3Bfont-style%3Anormal%3B%7D%3C%2Fstyle%3E%3C%2Fdefs%3E%3Ctext%20font-family%3D%22stixfd6acc6200cc0d68523933a987f%22%20font-size%3D%2214%22%20text-anchor%3D%22middle%22%20x%3D%228.5%22%20y%3D%2231%22%3E%26%23x3A3%3B%26%23x3C7%3B%3C%2Ftext%3E%3Ctext%20font-family%3D%22stixfd6acc6200cc0d68523933a987f%22%20font-size%3D%2214%22%20text-anchor%3D%22middle%22%20x%3D%2227.5%22%20y%3D%2231%22%3E%3D%3C%2Ftext%3E%3Cline%20stroke%3D%22%23000000%22%20stroke-linecap%3D%22square%22%20stroke-width%3D%221%22%20x1%3D%2240.5%22%20x2%3D%2291.5%22%20y1%3D%2227.5%22%20y2%3D%2227.5%22%2F%3E%3Ctext%20font-family%3D%22stixfd6acc6200cc0d68523933a987f%22%20font-size%3D%2214%22%20text-anchor%3D%22middle%22%20x%3D%2245.5%22%20y%3D%2214%22%3E%26%23x3C7%3B%3C%2Ftext%3E%3Ctext%20font-family%3D%22stixfd6acc6200cc0d68523933a987f%22%20font-size%3D%2210%22%20text-anchor%3D%22middle%22%20x%3D%2253.5%22%20y%3D%2221%22%3EA%3C%2Ftext%3E%3Ctext%20font-family%3D%22stixfd6acc6200cc0d68523933a987f%22%20font-size%3D%2214%22%20text-anchor%3D%22middle%22%20x%3D%2268.5%22%20y%3D%2214%22%3E%2B%3C%2Ftext%3E%3Ctext%20font-family%3D%22stixfd6acc6200cc0d68523933a987f%22%20font-size%3D%2214%22%20text-anchor%3D%22middle%22%20x%3D%2278.5%22%20y%3D%2214%22%3E%26%23x3C7%3B%3C%2Ftext%3E%3Ctext%20font-family%3D%22stixfd6acc6200cc0d68523933a987f%22%20font-size%3D%2210%22%20text-anchor%3D%22middle%22%20x%3D%2286.5%22%20y%3D%2221%22%3EB%3C%2Ftext%3E%3Ctext%20font-family%3D%22stixfd6acc6200cc0d68523933a987f%22%20font-size%3D%2214%22%20text-anchor%3D%22middle%22%20x%3D%2266.5%22%20y%3D%2243%22%3E2%3C%2Ftext%3E%3C%2Fsvg%3E)
- The difference in electronegativity between two elements A and B would be:
format('truetype')%3Bfont-weight%3Anormal%3Bfont-style%3Anormal%3B%7D%3C%2Fstyle%3E%3C%2Fdefs%3E%3Ctext%20font-family%3D%22math10074788632846aecf4793f2996%22%20font-size%3D%2214%22%20text-anchor%3D%22middle%22%20x%3D%227.5%22%20y%3D%2214%22%3E%26%23x2206%3B%3C%2Ftext%3E%3Ctext%20font-family%3D%22Times%20New%20Roman%22%20font-size%3D%2214%22%20text-anchor%3D%22middle%22%20x%3D%2217.5%22%20y%3D%2214%22%3E%26%23x3C7%3B%3C%2Ftext%3E%3Ctext%20font-family%3D%22math10074788632846aecf4793f2996%22%20font-size%3D%2214%22%20text-anchor%3D%22middle%22%20x%3D%2232.5%22%20y%3D%2214%22%3E%3D%3C%2Ftext%3E%3Ctext%20font-family%3D%22Times%20New%20Roman%22%20font-size%3D%2214%22%20text-anchor%3D%22middle%22%20x%3D%2247.5%22%20y%3D%2214%22%3E%26%23x3C7%3B%3C%2Ftext%3E%3Ctext%20font-family%3D%22Times%20New%20Roman%22%20font-size%3D%2210%22%20text-anchor%3D%22middle%22%20x%3D%2253.5%22%20y%3D%2219%22%3EA%3C%2Ftext%3E%3Ctext%20font-family%3D%22math10074788632846aecf4793f2996%22%20font-size%3D%2214%22%20text-anchor%3D%22middle%22%20x%3D%2264.5%22%20y%3D%2214%22%3E%26%23x2212%3B%3C%2Ftext%3E%3Ctext%20font-family%3D%22Times%20New%20Roman%22%20font-size%3D%2214%22%20text-anchor%3D%22middle%22%20x%3D%2274.5%22%20y%3D%2214%22%3E%26%23x3C7%3B%3C%2Ftext%3E%3Ctext%20font-family%3D%22Times%20New%20Roman%22%20font-size%3D%2210%22%20text-anchor%3D%22middle%22%20x%3D%2280.5%22%20y%3D%2219%22%3EB%3C%2Ftext%3E%3C%2Fsvg%3E)
- The average electronegativity of two elements, A and B would be:
The Bonding Triangle
The bonding triangle is used to determine the percentage of ionic, covalent and metallic character in an element or compound
- Since elements have zero difference in electronegativity they would be found along the x-axis depending on the electronegativity value of the individual element
- Ionic compounds have a large difference in electronegativity so would be located in the top centre part or apex of the triangle
- Covalent compounds with a low difference in electronegativity would be found in the bottom right and polar covalent compounds in the zone between ionic and covalent
Exam Tip
- You don't need to learn the bonding triangle as it is found in Section 17 of the Data Booklet
- Electronegativity values are found in the Periodic Table in Section 9.
