Difference between revisions of "SN1"
Line 12: | Line 12: | ||
Once the leaving group has shuffled off, the remaining carbocation's geometry changes. Where the target molecule had been tetrahedral with 4 sp3 bonds, the carbocation is trigonal planar with three sp2 orbitals and is flat. To either side, empty p orbitals invite attack. | Once the leaving group has shuffled off, the remaining carbocation's geometry changes. Where the target molecule had been tetrahedral with 4 sp3 bonds, the carbocation is trigonal planar with three sp2 orbitals and is flat. To either side, empty p orbitals invite attack. | ||
− | Depending on the composition of the three entities surrounding the carbon at the center of the carbocation or substrate, the result of the reaction may be different for attack at the front from attack at the back. If all 3 are different, then the result of the reaction will be a racemic mixture of left and right handed enantiomers, which may not be equally useful. | + | Depending on the composition of the three entities surrounding the carbon at the center of the carbocation or substrate, the result of the reaction may be different for attack at the front from attack at the back. If all 3 are different, then the result of the reaction will be a [racemic mixture] of left and right handed enantiomers, which may not be equally useful. |
Regardless of which side is attacked, a nucleophile clamps on creates an even larger carbocation. This promptly loses a proton to a base, usually the leaving group. | Regardless of which side is attacked, a nucleophile clamps on creates an even larger carbocation. This promptly loses a proton to a base, usually the leaving group. | ||
Line 19: | Line 19: | ||
*Leaving Groups | *Leaving Groups | ||
− | + | Halogens, particularly Bromine and Iodine, make great leaving groups. Their bond to carbon can be broken more easily. Chlorine is less desirable, and Fluorine, like unwanted in laws, almost never leaves. | |
*Nucleophiles | *Nucleophiles | ||
+ | Water is the simplest Nucleophile. | ||
*Solvents | *Solvents | ||
+ | |||
+ | |||
SN1 reactions work more favorably in a polar solvent. That carbocation will form more readily if the solvent can help the leaving group leave. | SN1 reactions work more favorably in a polar solvent. That carbocation will form more readily if the solvent can help the leaving group leave. |
Revision as of 19:38, 10 February 2016
This article is a stub. Please help Sciencemadness Wiki by expanding it, adding pictures, and improving existing text.
|
SN1 is an acronym for an Nucleophilic substitution reaction where the rate of the reaction is dependent on the concentration of one of the reactants:
(Substitution (Nucleophilic (1)reactant determines rate.
Counter intuitively, SN1 reactions proceed in two steps, the first of which is the rate determining step and the second of which occurs almost instantaneously. A good analogy is sitting down on a park bench where all the benches are occupied by sleeping vagrants. You wait for one to wake up and shamble off - then you sit down.
The more vagrants you have, the faster one will wake up and vacate a bench. In this scenario we call the vagrant a leaving group. The leaving group is an anion. When it leaves, the park bench becomes a carbocation, and is ready for it's Nucleophile.
Once the leaving group has shuffled off, the remaining carbocation's geometry changes. Where the target molecule had been tetrahedral with 4 sp3 bonds, the carbocation is trigonal planar with three sp2 orbitals and is flat. To either side, empty p orbitals invite attack.
Depending on the composition of the three entities surrounding the carbon at the center of the carbocation or substrate, the result of the reaction may be different for attack at the front from attack at the back. If all 3 are different, then the result of the reaction will be a [racemic mixture] of left and right handed enantiomers, which may not be equally useful.
Regardless of which side is attacked, a nucleophile clamps on creates an even larger carbocation. This promptly loses a proton to a base, usually the leaving group.
- Leaving Groups
Halogens, particularly Bromine and Iodine, make great leaving groups. Their bond to carbon can be broken more easily. Chlorine is less desirable, and Fluorine, like unwanted in laws, almost never leaves.
- Nucleophiles
Water is the simplest Nucleophile.
- Solvents
SN1 reactions work more favorably in a polar solvent. That carbocation will form more readily if the solvent can help the leaving group leave.
[Note: SN1 SN2, E1 and E2 are important and retaining the information has been difficult for me. I am writing this out for my benefit and yours using a variety of references and my own POV.]
to be continued.