Quote (Micrographia @ Jan 17 2015 03:39pm)
Anyone able to help with drawing the mechanisms for:
2-Bromopropane + Sodium Iodide in Acetone
2-Bromopropane + Silver Nitrate in Ethanol
For the first case, I know that: R-Br + NaI ---> R-I + NaBr
Pretty simple and straight forward. There should be an arrow going from the Iodine to the secondary carbon and an arrow from the single bond pushing the electrons onto the bromine. That should be it for the mechanism, correct?
Other things to remember about alkyl halides: In this case the 2-Bromopropane is symmetric. But for chiral molecules (2-Bromobutane, etc) the resulting molecule will have its chirality inversed.
The transition state has 5 members to it (typical of Sn2).
The resulting NaBr will be insoluble in acetone.
Speed of the reaction: primary > secondary > tertiary due to steric considerations.
This reactants must be absolutely dry (no protic nor polar residual solvent).
Acetone is aprotic. Acetone has a low dielectric polarization, so it won't participate in the reaction (i.e. avoids solvolysis).
Quote (Micrographia @ Jan 17 2015 03:39pm)
Second case, I know that: R-Br --> R-OC2H5 + AgBr
I'm just not sure how to accurately draw this one. I'm assuming that this one is a two step?
Thanks
Yes, two-step Sn1 reaction. The alkyl can form a stable carbocation where the nitrate is the counter ion -- definitely Sn1. Then the nucleophilic ethanol attacks the carbocation, leading to the formation of an ether. The leftover proton will acidify the ethanol solvent.
Although the 2-Bromopropane is not chiral, you should a racemic mixture if the reaction does involve a chiral alkyl halide (2-Bromobutane, etc).
The resulting silver bromine is insoluble in ethanol.