Nucleophilic Addition to Carbonyl Compounds

Here's an example of a nucleophilic addition reaction to an aldehyde or a ketone. So over here on the left, right, it could be an aldehyde or you could change that to form a ketone. If you add water to an aldehyde or a ketone, you form this product over here on the right, which is called a hydrate or also called a gem diol or geminal diol because these two OHs here are on the same carbon, so they're like twins. And this reaction is at equilibrium. So let's think about the aldehyde or the ketone. We know the carbonyl in aldehyde or ketone is polarized, so we know that the oxygen is more electronegative than carbon, so it withdraws some electron density. So this oxygen here is partially negative, and this carbonyl carbon is partially positive, like that. And therefore, the carbonyl carbon, since it's partially positive, is electrophilic, so it wants electrons, and it can get electrons from water. So let's go ahead and draw the water molecule right here. Water can function as a nucleophile, right? It has two lone pairs of electrons. This oxygen here is partially negative. And so we're going to get a nucleophile attacking our electrophile. So a lone pair of electrons on the oxygen is going to attack our carbonyl carbon like that. So the nucleophile attacks the electrophilic portion of the molecule. And these pi electrons here kick off onto the oxygen. So let's go ahead and draw the result of our nucleophilic attack here. And so we now have our oxygen. Alright, bonded to this carbon. And this oxygen still has two hydrogens bonded to it. So I'm gonna go ahead and draw on those two hydrogens. There's still a lone pair of electrons on that oxygen, which gives that oxygen a plus one formal charge. And then this carbon here is bonded to another oxygen, which had two lone pairs of electrons around it, and now it picked up another one, so a negative one formal charge on this oxygen. and there's still an R group bonded to it and a hydrogen over here, like that. And so let's try to follow some electrons here. So one of the lone pairs of electrons on the oxygen formed a bond with our carbon. So I'm saying that these electrons are right here, like that. And then we can think about our pi electrons. Alright, so our pi electrons in here is kicking off onto our oxygen, so it doesn't really matter which one of these three it is, right, let's just say it's that one. And we get this as our intermediate. And so next, we can think about an acid-base reaction. So another water molecule comes along right here, and so we know water can function as an acid or a base, and so this lone pair of electrons could take, let's say it takes this proton right here and leaves these electrons behind on our oxygen. So let's go ahead and draw the result of that acid-base reaction. And so we would have our oxygen here, would now be bonded to only one hydrogen. And let's see, we still have our negatively charged oxygen over here on the right. And then we have our R group and our hydrogen like that. And we still have this lone pair of electrons. We just picked up another lone pair of electrons. Let me go ahead and show those. So let me go ahead and use blue for those electrons. So these electrons in here ended up on this oxygen. And so we're almost to our final product. We've almost formed our hydrate. We just need to do one more acid-base reaction. So of course, another water molecule could come along. So water can function as an acid or a base. And a lone pair of electrons on this oxygen could take this proton and leave these electrons behind. And then that, of course, would give us our final product. So that would give us our hydrate over here. And you could, of course, change this hydrogen to an R prime, change this hydrogen to an R prime if you wanted to. And you would get this over here, so your hydrate or your gem diol. And so that's the That's the general mechanism for uncatalyzed reaction here. Let's look at some examples. And it's important to remember that this reaction is at equilibrium. And so let's look at three examples. Our first example is formaldehyde. So if you react formaldehyde with water, you form your hydrate over here on the right. And in this case, the equilibrium is to the right, favors the formation of the hydrate, and that's because aldehydes are very reactive. And we talked about why in the video on the reactivity of aldehydes and ketones, right? So we have a very polarized carbonyl situation here, so this carbon right here is partially positive. And we have these hydrogens here, which don't take up a whole lot of space, and so we have greater polarization in ketones and also decreased steric hindrance. And so, because of the high reactivity of aldehydes, then this product is favored. All right, if we look at the next reaction, we no longer have an aldehyde. This is a ketone, this is acetone. And so adding water to acetone gives us this as our product for our hydrate. Except we know that ketones are not as reactive as aldehydes, and so this time the equilibrium is to the left. So it favors the formation of the ketone. Let's look at another one. So this is acetaldehyde. And so if we add water to acetaldehyde over here, we form this as our hydrate product. And once again, we know that these reactions occur because of our carbonyl carbon right here being partially positive, right? So the oxygen withdraws some electron density like that. So we could make aldehydes or ketones more reactive by adding something else that withdraws electron density from that carbonyl carbon. And one thing you could do is add an electronegative atom like a halogen. So let's go ahead and do that. Let's add three... Let's add three halogens here. Let's add three chlorines to this carbon, the one adjacent to our carbonyl carbon. And those electron withdrawing groups, those very electronegative atoms, withdraw some electron density. So they're going to withdraw electron density this way, once again, away from our carbonyl carbon. And so this carbonyl carbon gets even more partially positive. by the addition of these electronegative atoms. And the more positive you make that carbonyl carbon, the more electrophilic you make it, and therefore, the more the nucleophile, which is water, is going to attack. And so you make it even more reactive by adding these. And so you can push the equilibrium even more. To the right, you can form more of your product. And so let's go ahead and draw the product of that reaction. So we would put three chlorines on here like that. And so you could also do this with ketones, and you could make ketones much more reactive by doing that. And so this particular reaction is a little bit famous. Over here on the left is trichloroacetaldehyde. And then once you form the hydrate of that, you form chloral hydrate. And this is famous for being knockout drops. And so some of the old references to it are slip someone a Mickey Finn. So you could slip chloral hydrate into someone's drink and it was a knockout drop situation. And so just a little bit of an interesting reaction here for formation of hydrates.

So let's think about the aldehyde or the ketone. We know the carbonyl in aldehyde or ketone is polarized, so we know that the oxygen is more electronegative than carbon, so it withdraws some electron density. So this oxygen here is partially negative, and this carbonyl carbon is partially positive, like that. And therefore, the carbonyl carbon, since it's partially positive, is electrophilic, so it wants electrons, and it can get electrons from water. So let's go ahead and draw the water molecule right here.

Water can function as a nucleophile, right? It has two lone pairs of electrons. This oxygen here is partially negative. And so we're going to get a nucleophile attacking our electrophile.

So a lone pair of electrons on the oxygen is going to attack our carbonyl carbon like that. So the nucleophile attacks the electrophilic portion of the molecule. And these pi electrons here kick off onto the oxygen.

So let's go ahead and draw the result of our nucleophilic attack here. And so we now have our oxygen. Alright, bonded to this carbon.

And this oxygen still has two hydrogens bonded to it. So I'm gonna go ahead and draw on those two hydrogens. There's still a lone pair of electrons on that oxygen, which gives that oxygen a plus one formal charge.

And then this carbon here is bonded to another oxygen, which had two lone pairs of electrons around it, and now it picked up another one, so a negative one formal charge on this oxygen. and there's still an R group bonded to it and a hydrogen over here, like that. And so let's try to follow some electrons here.

So one of the lone pairs of electrons on the oxygen formed a bond with our carbon. So I'm saying that these electrons are right here, like that. And then we can think about our pi electrons. Alright, so our pi electrons in here is kicking off onto our oxygen, so it doesn't really matter which one of these three it is, right, let's just say it's that one.

And we get this as our intermediate. And so next, we can think about an acid-base reaction. So another water molecule comes along right here, and so we know water can function as an acid or a base, and so this lone pair of electrons could take, let's say it takes this proton right here and leaves these electrons behind on our oxygen. So let's go ahead and draw the result of that acid-base reaction.

And so we would have our oxygen here, would now be bonded to only one hydrogen. And let's see, we still have our negatively charged oxygen over here on the right. And then we have our R group and our hydrogen like that. And we still have this lone pair of electrons.

We just picked up another lone pair of electrons. Let me go ahead and show those. So let me go ahead and use blue for those electrons. So these electrons in here ended up on this oxygen.

And so we're almost to our final product. We've almost formed our hydrate. We just need to do one more acid-base reaction. So of course, another water molecule could come along.

So water can function as an acid or a base. And a lone pair of electrons on this oxygen could take this proton and leave these electrons behind. And then that, of course, would give us our final product.

So that would give us our hydrate over here. And you could, of course, change this hydrogen to an R prime, change this hydrogen to an R prime if you wanted to. And you would get this over here, so your hydrate or your gem diol. And so that's the That's the general mechanism for uncatalyzed reaction here. Let's look at some examples.

And it's important to remember that this reaction is at equilibrium. And so let's look at three examples. Our first example is formaldehyde. So if you react formaldehyde with water, you form your hydrate over here on the right. And in this case, the equilibrium is to the right, favors the formation of the hydrate, and that's because aldehydes are very reactive.

And we talked about why in the video on the reactivity of aldehydes and ketones, right? So we have a very polarized carbonyl situation here, so this carbon right here is partially positive. And we have these hydrogens here, which don't take up a whole lot of space, and so we have greater polarization in ketones and also decreased steric hindrance. And so, because of the high reactivity of aldehydes, then this product is favored. All right, if we look at the next reaction, we no longer have an aldehyde.

This is a ketone, this is acetone. And so adding water to acetone gives us this as our product for our hydrate. Except we know that ketones are not as reactive as aldehydes, and so this time the equilibrium is to the left. So it favors the formation of the ketone. Let's look at another one.

So this is acetaldehyde. And so if we add water to acetaldehyde over here, we form this as our hydrate product. And once again, we know that these reactions occur because of our carbonyl carbon right here being partially positive, right?

So the oxygen withdraws some electron density like that. So we could make aldehydes or ketones more reactive by adding something else that withdraws electron density from that carbonyl carbon. And one thing you could do is add an electronegative atom like a halogen.

So let's go ahead and do that. Let's add three... Let's add three halogens here. Let's add three chlorines to this carbon, the one adjacent to our carbonyl carbon. And those electron withdrawing groups, those very electronegative atoms, withdraw some electron density.

So they're going to withdraw electron density this way, once again, away from our carbonyl carbon. And so this carbonyl carbon gets even more partially positive. by the addition of these electronegative atoms. And the more positive you make that carbonyl carbon, the more electrophilic you make it, and therefore, the more the nucleophile, which is water, is going to attack.

And so you make it even more reactive by adding these. And so you can push the equilibrium even more. To the right, you can form more of your product.

And so let's go ahead and draw the product of that reaction. So we would put three chlorines on here like that. And so you could also do this with ketones, and you could make ketones much more reactive by doing that. And so this particular reaction is a little bit famous.

Over here on the left is trichloroacetaldehyde. And then once you form the hydrate of that, you form chloral hydrate. And this is famous for being knockout drops. And so some of the old references to it are slip someone a Mickey Finn. So you could slip chloral hydrate into someone's drink and it was a knockout drop situation.

And so just a little bit of an interesting reaction here for formation of hydrates.

Transcript for:Nucleophilic Addition to Carbonyl Compounds

Transcript for:
Nucleophilic Addition to Carbonyl Compounds