Simple method for writing Lewis Structures – Ozone O3 and carbonate CO3-2

A simple procedure for writing Lewis structures is given in a previous article entitled “Lewis Structures and the Octet Rule”.

Examples for writing Lewis structures following the above procedure are given bellow:

Consider the case of ozone O₃:

Step1: The central atom will be one of the oxygen atoms.  Connect the 3 atoms with a single bonds

O – O – O

             

Step 2: Calculate the # of electrons in π bonds (multiple bonds) using formula (1) in the article entitled “Lewis Structures and the Octet Rule”.

Where n in this case is 3 since O₃ consists of three atoms

Where V = (6 + 6 + 6 )  = 18  

Therefore, P = 6n + 2 – V = 6 * 3 + 2 – 18 = 2      Therefore, there are 2 π electrons in O₃  and so 1 double   bond must be added to the structure of Step 1.

Step 3 & 4:  The 2 atoms are joined together with a double bond. Therefore the Lewis structure for O₃ is as follows:





Figure 1: Lewis structures for O_3. There are two equivalent resonance structures so in the molecule the bond between the O atoms is something between a double and a single bond. This fact has been proved experimentally

 

Consider the case of the carbonate ion, CO₃^-2

Carbonate species act as buffers and are necessary for all biological systems. They also play important role in neutralization of strong acids and bases. The carbonate system as it is called is the major source of buffering in the ocean and in natural waters.

Step1: The central atom will be the C atom since it is the only atom with “subscript” equal to 1 in the molecular formula.  Connect the O atoms with the C atom with single bonds

             

Step 2: Calculate the # of electrons in π bonds (multiple bonds) using  formula (1) in the article entitled “Lewis Structures and the Octet Rule”.:

Where n in this case is 4 since CO₃^-2 consists of four atoms

Where V = (4 + 6 + 6 + 6 ) – (-2)  = 24  

Therefore, P = 6n + 2 – V = 6 * 4 + 2 – 24 = 2      \  there are 2 π electrons in  CO₃^-2  \

1 double   bond must be added to the structure of Step 1.

Step 3 & 4: One double bond between C and O is added to the structure in step 1. Unshared electron pairs are added so that there is an octet of electrons around each atom. All the equivalent resonance structures are drawn by delocalizing electron pairs. Therefore, the Lewis structures for CO₃^-2  are as follows:

Figure 2: Lewis structures for the carbonate ion CO₃^-2. The 3 structures are equivalent since they have equal formal charges on the elements. It has been proven experimentally that the C-O bond in the carbonate ion is a hybrid of a single and a double bond (the length of the C-O bond in the carbonate ion is approximately half of the sum of the lengths of a normal C-O and C=O bond).This means that the theoretical Lewis structures are in agreement with experimental results.