The common oxidation states of the Group 1, 2 and
elements are given below with the most stable oxidation state marked with an asterisk (*). The most stable state is usually the naturally-ocurring one. These can be used to predict the redox reactivity of the elemental form and of ions/molecules containing these elements in combination with other elements.
| Group 1 | Li | Na | K | Rb | Cs |
| ns1 | +1* | +1* | +1* | +1* | +1* |
| | 0 | 0 | 0 | 0 | 0 |
| | | | | | |
| Group 2 | Be | Mg | Ca | Sr | Ba |
| ns2 | +2* | +2* | +2* | +2* | +2* |
| | 0 | 0 | 0 | 0 | 0 |
| |
| Group 13 | B | Al | Ga | In | Tl |
| ns2 np1 | +3* | +3* | +3* | +3* | +3 |
B and Al have ill-defined
negative oxidation states | +1 | +1* |
| | 0 | 0 | 0 | 0 | 0 |
sOn completion of the module, for Group 1, 2 and
elements, you should be able, on the basis of the given information
- to identify whether a given oxidation state can act as a reductant, an oxidant or both
- to identify the relative strengths of the various oxidation states as reductants or oxidants
- to identify whether an element in a particular oxidation state will react with a common reductant (iodide ion) or a common oxidation (permanganate ion)