Halogenoalkanes contain polar bonds due to the halogens being more electronegative than carbon atoms, forming ∂+ and ∂- regions.
Nucleophiles are species that are 'positive liking', containing a lone electron pair that is attracted to ∂+ regions of molecules.
Some of the most common nucleophiles are CN-, NH3, and OH-.
Nucleophilic Substitution is the reaction mechanism that shows how nucleophiles attack halogenoalkanes, producing alcohols or amines.
The intermediate formed in the mechanism for amines has an N+ atom, so electrons are transferred to it causing a hydrogen to be lost too.
The greater the Mr of the halogen in the polar bond, the lower the bond enthalpy, meaning it can be broken more easily.
Nucleophilic substitution reactions can only occur for 1o (primary) and 2o (secondary) halogenoalkanes.
When a halogenoalkane is heated to high temperatures under alcoholic conditions, elimination occurs, resulting in the formation of a carbon-carbon double bond, an alkene.
Elimination reactions can only occur from 2o and 3o (tertiary) halogenoalkanes.
Ozone in the atmosphere absorbs UV radiation, and CFCs (chloro-fluoro carbons) also absorb UV radiation, breaking down the carbon-halogen bonds to form free radicals that can catalyse ozone depletion.
CFC-free solvents are now being produced to prevent them entering the atmosphere, helping to minimise ozone depletion and global warming.