- [Instructor] The S N
1 and S N 2 reactions
involve leaving groups.
Let's look at this pKa table
to study leaving groups in more detail.
On the left, we have the acid.
For example, hydroiodic acid, HI,
with an approximate pKa of negative 11.
Remember, the lower the pKa value,
the stronger the acid.
So on this table with the
pKa value of negative 11,
hydroiodic acid is the strongest acid
and the stronger the acid,
the more stable the conjugate base.
So the conjugate base to HI
is I minus the iodide anion.
And since this is the conjugate
based to the strongest acid,
this is the most stable base.
Let me write that down here.
This is the most stable base on the table,
which means that the iodide anion
is an excellent leaving group
because it is very stable.
Next, we have hydrobromic acid,
approximate pKa of negative nine.
So the conjugate base
would be the bromide anion,
so also a stable conjugate base.
So therefore, a good leaving group.
For HCl, it's the chloride anion,
also a good leaving group.
So you see these halide anions
as leaving groups all the
time in organic mechanisms.
Let me write this down here.
So these are all examples
of
good
leaving
groups.
Next, let's look at this
acid on the left here.
This is p-Toluenesulfonic acid
with a pKa value of negative three,
so it's still pretty acidic.
The conjugate base to
this is on the right here
and we call this anion a tosylate group.
Let me write this down.
This is called a tosylate group.
And since it's kind of a bulky group,
instead of drawing this out all the time,
you often see OTs written.
So, OTs,
like that,
and you could put a negative charge
on the oxygen here if you wanted to.
So you'll see the tosylate group
function as a leaving
group in many reactions.
Let's look at an example of another acid.
So if I move down here to
H3O+, the hydronium ion,
with a pKa value of negative two.
The conjugate base to H3O+ is H2O
and water is also a good leaving group.
So let's go back up here to the topic
and we can see that all the
acids that we talked about
have negative pKa values,
so negative 11, negative
nine, negative seven,
negative three, and negative two.
And notice all of the conjugate bases
are good leaving groups.
So you can say that if an acid
has a negative value for the pKa,
the conjugate base will
be a good leaving group.
Let's look at another example of an acid.
So, water.
Water's pKa value is positive 15.7,
so it's not a very strong acid.
The conjugate base to water
is the hydroxide anion, OH-,
and this is a bad leaving group.
So hydroxide ion is a bad leaving group
and that's because water
is not a strong acid.
Look at this value for the pKa,
positive 15.7.
So if we look at ethanol,
similar story here.
So ethanol has a pKa value of positive 16.
So the ethoxide anion is
not a good leaving group,
so this pKa values are in the positive
and these conjugate bases
must not be very stable
which means they are bad leaving groups.
Let me write that down here.
So these are examples
of bad leaving groups.
Both S N 1 and S N 2 reactions
need good leaving groups.
However, the S N 1 reaction
is even more sensitive.
Let's look at tert-Butyl chloride.
Let's say it's reacting
via an S N 1 mechanism.
The first step should be
loss of leaving group.
So these electrons come
off onto the chlorine.
We would form the chloride anion
which has a negative one formal charge.
We just saw on our pKa table
that the chloride anion is
a stable conjugate base.
So therefore, this is
a good leaving group.
We're taking a bond away
from the carbon in red,
so the carbon in red gets
a plus one formal charge
and we form a tertiary
carbocation as well.
Since this is the rate determining step
of our S N 1 mechanism,
the formation of our stable anion,
this formation of a good leaving group
helps the S N 1 mechanism occur.
Next, let's look at this alcohol here.
If we approach it the same way
as we did in the previous problem
and we said, "Okay, first step
is loss of the leaving group
"and these electrons come
off onto the oxygen."
Think about what leaving group that is.
That would be the hydroxide ion
which we know from our pKa table
is not a good leaving group.
So the hydroxide ion
is not as stable of an
anion as the chloride anion.
So the chloride anion
is a good leaving group.
The hydroxide anion is
a bad leaving group.
So that's not the first
step of this mechanism.
We need to make a better leaving group
and you can do that by
having a proton source.
Let's say we have a source of
protons, an acid in solution,
so let's say there's an H+ here.
The first step would be
to protonate our alcohol,
so our alcohol is gonna act as a base
and pick up a proton.
Let's draw the results of that.
We have our ring.
Let's put in that methyl group.
And now our oxygen is
bonded to two hydrogens.
There's still a lone pair
of electrons on this oxygen
which give the oxygen a plus,
which gives the oxygen a
plus one formal charge.
So the electrons here
in magenta, let's say,
pick up this proton to form this bond.
Now we're ready for
loss of a leaving group
because if these electrons
come off onto the oxygen now,
we form water as a leaving group.
Let me draw that in here.
So here is the water molecule.
Let me highlight those electrons in blue.
These electrons come off onto
the oxygen then we form water
and we know from our pKa table
that water is a good leaving group.
We're taking a bond away
from this carbon in red,
so we're also gonna form
a tertiary carbocation.
Let me draw that in here.
Here's our ring.
Here's our methyl group.
A plus one formal charge
on the carbon in red.
So by thinking about your pKa values,
you can determine the
stability of the conjugate base
and therefore, if a leaving group
is a good leaving group
or a bad leaving group
and that helps you out when
you're drawing mechanisms.