Question

write the substitution reaction of methane with chlorine mention the catalyst used here?

Answer 1

The facts

When a mixture of methane and chlorine is exposed to ultraviolet light - typically sunlight - a substitution reaction occurs and the organic product is chloromethane.

CH4  +  Cl2CH3Cl  +  HCl

However, the reaction doesn't stop there, and all the hydrogens in the methane can in turn be replaced by chlorine atoms. That means that you could get any of chloromethane, dichloromethane, trichloromethane or tetrachloromethane.

CH4  +  Cl2CH3Cl  +  HClCH3Cl  +  Cl2CH2Cl2  +  HClCH2Cl2  +  Cl2CHCl3  +  HClCHCl3  +  Cl2CCl4  +  HCl

You might think that you could control which product you got by the proportions of methane and chlorine you used, but it isn't as simple as that. If you use enough chlorine you will eventually get CCl4, but any other proportions will always lead to a mixture of products.

The mechanisms

The formation of multiple substitution products like di-, tri- and tetrachloromethane can be explained in just the same sort of way as the formation of the original chloromethane. You just have to look at the likely collisions as the reaction progresses.

Making dichloromethane

You will remember that the over-all equation for the first stage of the reaction is

CH4  +  Cl2CH3Cl  +  HCl

As the reaction proceeds, the methane is getting used up and chloromethane is taking its place. That means that the argument about what a chlorine radical is likely to hit changes during the course of the reaction. As time goes by there is an increasing chance of it hitting a chloromethane molecule rather than a methane molecule.

When that happens, the chlorine radical can take a hydrogen from the chloromethane just as well as it could from a methane. In this new case:

CH3Cl  +  ClCH2Cl  +  HCl

Notice:  The dot representing the electron has been moved against the carbon which is the atom with the unpaired electron. It would be potentially confusing to leave it next to the chlorine.

The chloromethyl radical formed can then interact with a chlorine molecule in a new propagation step . . .

 CH2Cl  +  Cl2CH2Cl2  +  Cl

. . . and so dichloromethane is formed and a chlorine radical regenerated.

These propagation steps continue until the chain is terminated by any two radicals colliding and combining together.

Answer 2

Answer:

Only names i have written.

i)chloro methane

ii)dichloro methane

iii)chloroform

iv)carbon tetra chlora.