A simple procedure for writing Lewis structures is given in a previous article entitled “Lewis Structures and the Octet Rule”. Relevant worked examples were given in the following articles: Examples #1, #2, #3 , #4, #5, #6, #7, #8, #9, #10, #11, #12, #13, #14, #15, #16, #17, #18, #19, #20, #21, #22, #23, #24, #25, #26, #27, #28, #29, #30.
Let us consider the case of the CN+cation:
Step 1: Connect the atoms with single bonds.
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| Fig. 1: Connect the C and N atoms with a single bond |
Where n in this case is 2 since CN+ consists of 2 atoms.
Where V = (4 + 5 ) - charge = 9 – 1 = 8
Therefore, P = 6n + 2 – V = 6 *2 + 2 – 8 = 6 Therefore there are 6 πelectrons. So, there are 1) either 3 double bonds 2) or 1 triple bond and an unshared electron pair.
Two atoms cannot be connected with 3 double bonds. However, it is possible that will be connected by a double bond. Two unshared electron pairs will be also added – so that in total 6 π electrons will be present :
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| Fig. 2: Lewis electron dot structures for the CN+ion. Structures 2 and 3 are minor contributors because of large charge separation. Structure 1 is a weak contributor too because the positive charge is on N which is more electronegative element than C. |
Another possibility is that the two atoms will be connected by a triple bond. In this case an unshared electron pair will be added so that 6π electrons will be present. The Lewis structures of the CN+cation are as follows:
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| Fig. 3: Lewis electron dot structures for the CN+ion. Structure 4 is a major contributor because the positive charge is on the least electronegative atom (C atom). Structure 5 is a minor contributor because of large charge separation. |
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