Philippa B. Cranwell

Foundations of Chemistry


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      0.6.2 Multiplying and dividing numbers

      When multiplying numbers written in scientific notation, the coefficients (i.e. the numbers in front of the 10n) are multiplied and the exponents are added. So, for example:

equation

      When dividing numbers written in scientific notation, the coefficients are divided and the exponents subtracted. So, for example:

equation

      Worked Example 0.8

      Calculate the answers to the following expressions, and present your result in scientific notation:

      1 7.5 × 5.7 =

      2 (6.4 × 102) × (1.30 × 104) =

      3 (1.751 × 10−3) × (59.0 × 10−2) =

      4 1.435 × 10−2 ÷ 2.9 × 10−4 =

       Solution

      1 7.5 × 5.7 = 42.75 = 43 = 4.3 × 101The smallest number of significant figures is two, so this becomes 43 after reducing the number of significant figures and rounding.

      2 (6.4 × 102) × (1.30 × 104) = 8.32 × 106 = 8.3 × 106The smallest number of significant figures is two, so 8.32 becomes 8.3 after reducing the number of significant figures.

      3 (1.751 × 10−3) × (59.0 × 10−2) = 103.309 × 10−5 = 1.033 09 × 10−3 = 1.03 × 10−3The smallest number of significant figures is three, so 1.03309 becomes 1.03 after reducing the number of significant figures.

      4  = 4.9 × 101The smallest number of significant figures is two, so 4.948 × 101 becomes 4.9 × 101 after reducing the number of significant figures and rounding down. This would normally be written as 49.

      0.7.1 Writing chemical formulae

      Most people are familiar with H2O and CO2 as the formulae that represent water and carbon dioxide, respectively.

      A chemical compound has a formula that represents the type and number of atoms in that compound. The plural of ‘formula’ is ‘formulae’ as the word derives from Latin.

      The letters in the formulae represent the elements in the periodic table, and the numbers given as subscripts after the letters indicate how many atoms of each element are in one unit of the compound. The formula H2O tells us there are two atoms of hydrogen (H) and one atom of oxygen (O) in one molecule of the compound. In CO2, there is one atom of carbon and two atoms of oxygen.

      The terms ‘atom’ and ‘molecule’ will be explained fully in Chapter 1.

      In the formulae of some compounds, there may be atoms enclosed in brackets (or parentheses): for example, Ca(NO3)2, the formula for calcium nitrate. The formula indicates that in one formula unit of calcium nitrate, there is one atom of calcium (Ca), two atoms of nitrogen (N), and six atoms of oxygen (O). The brackets act as a multiplier, multiplying all the atoms inside the bracket by the number in subscript outside the bracket.

Common cations Common anions
Symbol Name Charge Symbol Name Charge
Na+ Sodium +1 F Fluoride −1
K+ Potassium +1 Cl Chloride −1
Mg2+ Magnesium +2 Br Bromide −1
Ca2+ Calcium +2 O2− Oxide −2
Al3+ Aluminium +3 S2− Sulfide −2
Cu2+ Copper +2 CO32− Carbonate −2
Fe2+ Iron +2 SO42− Sulfate −2
Ag+ Silver +1 NO3 Nitrate −1
Zn2+ Zinc +2 PO43− Phosphate −3
NH4+ Ammonium +1 OH Hydroxide −1

      Salts are neutral substances made up of positive cations and negative anions in a ratio that ensures the overall charge on the salt is zero. For example, aluminium sulfate is composed of aluminium (Al3+) ions and sulfate (SO42−) ions. Because the salt is neutral overall, the formula must be Al2(SO4)3.

      0.7.2 Writing and balancing chemical