Alkenes: Stability of Cations & Markovnikov's Rule
- Carbocations are positively charged carbon atoms with only three covalent bonds instead of four
- There are three types of carbocations: primary, secondary and tertiary
Inductive effect
- The alkyl groups attached to the positively charged carbon atoms are ‘electron donating groups’
- This is also known as the inductive effect of alkyl groups
- The inductive effect is illustrated by the use of arrowheads on the bonds
- The alkyl groups push electrons away from themselves towards the positively charged carbon
- This causes the carbocation to become less positively charged
- As a result of this, the charge is spread around the carbocation which makes it energetically more stable
- This means that tertiary carbocations are the most stable as they have three electron-donating alkyl groups which energetically stabilise the carbocation
- Due to the positive charge on the carbon atom, carbocations are electron-loving species (electrophiles)
Alkyl groups push electron density towards the carbocation making it energetically more stable; the more alkyl groups the carbocation is bonded to, the more stabilised it is
Markovnikov’s rule
- In addition reactions, an electrophile reacts with the double bond of alkenes
The electrophile reacts with the electron-rich C-C double bond
- The electrophile will add to the carbon to give the most stable carbocation
The most stable carbocation is the major product of the nucleophilic attack on the C-C double bond
- Therefore, the nucleophile will bond to the C-C carbon atom with the highest number of alkyl groups bonded to it
The nucleophile ends up to the most substituted C-C carbon atom
- This is also known as the Markovnikov’s rule which predicts the outcome of addition reactions and states that:
In an addition reaction of a halogen halide (HX) to an alkene, the halogen ends up bonded to the most substituted carbon atom.
