Alcohol Reactions - HBr, PBr3, SOCl2 - By The Organic Chemistry Tutor
Transcript
| 00:0-1 | in this video , we're going to go over reactions | |
| 00:03 | associated with alcohols . So what's going to happen if | |
| 00:07 | we react and alcohol with hydrochloric acid , the O | |
| 00:12 | . H group will be replaced with a booming adam | |
| 00:15 | . So that's going to be the end result . | |
| 00:18 | And so basically the alcohol is converted into an alcohol | |
| 00:22 | light . But now let's go over the mechanism for | |
| 00:25 | this reaction that we have a primary alcohol . And | |
| 00:29 | so the mechanism will go through an S . And | |
| 00:32 | T . Reaction . But the first step in this | |
| 00:35 | reaction will be pronation of the O . H group | |
| 00:39 | . The O . H group is a bad leaving | |
| 00:41 | group , but once you add a hydrogen to it | |
| 00:44 | , it becomes a good leaving group . So the | |
| 00:48 | oxygen is going to acquire a hydrogen turning into this | |
| 00:52 | species . And so whenever the oxygen has a positive | |
| 00:57 | charge , it becomes about to leave the group . | |
| 01:01 | In the 2nd step , the bromide ion , which | |
| 01:05 | is now in the solution will attack from the back | |
| 01:08 | in an S and T . Reaction , expelling H | |
| 01:10 | 21 and so that's how we can get our alcohol | |
| 01:14 | headlight . So that's the mechanism for the conversion of | |
| 01:17 | a primary alcohol into an alcohol . Light . Primary | |
| 01:23 | alcohols react very slowly with hydrochloric acid due to the | |
| 01:28 | fact that chloride is a weaker nuclear file than bromine | |
| 01:33 | . However , this reaction can be enhanced if we | |
| 01:37 | use sync chloride , which is a powerful lewis acid | |
| 01:41 | . And so this is known as the Lucas regent | |
| 01:45 | . So this oxygen is going to attack zinc chloride | |
| 01:51 | but I need to draw this better . So I'm | |
| 02:00 | going to draw a zinc chloride like this so the | |
| 02:04 | oxygen attacks sink and it's going to expel a chloride | |
| 02:08 | ion . And so we're going to have an oxygen | |
| 02:12 | that's attached to a hydrogen and the zinc species . | |
| 02:19 | So right now the oxygen has a positive charge , | |
| 02:22 | which means it's a good leaving group . So in | |
| 02:25 | the second step , the chloride ion comes in , | |
| 02:28 | it attacks the carbon kicks out the oxygen and so | |
| 02:32 | that's how we can get our , I'll kill hey | |
| 02:35 | life . So if you want to convert an alcohol | |
| 02:39 | into an alcohol chloride where you have a primary alcohol | |
| 02:44 | , you want to use the Lucas re agent to | |
| 02:46 | do . So now let's work on some more examples | |
| 02:49 | . Let's say we have a tertiary alcohol . And | |
| 02:52 | this time let's react with hydrochloric acid . What is | |
| 02:57 | the major product in its reaction ? The end result | |
| 03:01 | is that we're going to replace the O . H | |
| 03:03 | . Group with the iodine atom . And so that's | |
| 03:07 | going to be the enemy . So , but let's | |
| 03:09 | propose a mechanism . So because we have a tertiary | |
| 03:13 | alcohol , this reaction Will proceed by the SM one | |
| 03:19 | mechanism . But the first step is pronation . We | |
| 03:27 | need to convert the hydroxy group into a good leaving | |
| 03:31 | group . So now because it's an S . M | |
| 03:37 | . one reaction , the iodide ion , it's not | |
| 03:40 | going to come in and attack this card and that's | |
| 03:42 | gonna be an S . And T . Reaction . | |
| 03:45 | Those method groups will prevent access to this carbon . | |
| 03:50 | So what's going to happen is that is the lever | |
| 03:53 | group is going to leave given us a treasury car | |
| 03:58 | bulkhead in intermediate . And then at this point that's | |
| 04:02 | when the iodide ion can come in and combined with | |
| 04:06 | the carbon iodine given us and alcohol , light . | |
| 04:11 | And so this is the product of the reaction . | |
| 04:15 | Now let's go ahead and work on another example . | |
| 04:21 | So let's react this alcohol . This is uh two | |
| 04:26 | methods cyclo hexane all let's react it with hydrochloric acid | |
| 04:32 | . So go ahead and predict the major product of | |
| 04:33 | the reaction and how soon sure mechanism as well . | |
| 04:39 | So the first step is pro nation , as always | |
| 04:42 | anytime you react and alcohol with an asset . So | |
| 04:53 | now we have a good leaving group . So what's | |
| 05:00 | going to happen is the leaving group is going to | |
| 05:02 | leave and once it leaves we're going to have a | |
| 05:08 | secondary carbon cat eye . But notice that the secondary | |
| 05:13 | car market is next to a tertiary carbon . And | |
| 05:16 | so when you see that hydride shift will occur . | |
| 05:20 | And so this is going to give us a more | |
| 05:23 | stable tertiary carbo Ketan intermediate . And then at this | |
| 05:28 | point the bromide ion will attack the carbo Can I | |
| 05:32 | ? And so this is going to be the final | |
| 05:35 | answer . So we have a tertiary alcohol life and | |
| 05:40 | that's it . Now there are other ways in which | |
| 05:44 | we can convert alcohols into alcohol . Lights one re | |
| 05:49 | agent that we could use is PBR three And this | |
| 05:53 | works through an S . and two mechanism converting the | |
| 05:56 | O . H . Group into or replace them for | |
| 06:00 | Berman adam . And so this produces an alcohol bromide | |
| 06:04 | . Another example Is using s . o . c | |
| 06:07 | . l . two which also works through an S | |
| 06:10 | . And T . Mechanism . But this time the | |
| 06:12 | O . H . Group is replaced with the CIA | |
| 06:15 | . Now let's go over the mechanism for those two | |
| 06:18 | reactions . Let's begin by drawn one . Beautiful And | |
| 06:26 | then PBR three looks like this . This is phosphorus | |
| 06:30 | try bromide . The phosphorus atom has a lone pair | |
| 06:39 | . Now phosphorus is partially positive . Yeah the reason | |
| 06:46 | for that is bro ming is more electro negative than | |
| 06:50 | phosphorus . So brahman is partially negative . Yeah . | |
| 06:57 | Now the oxygen in the alcohol also has a partial | |
| 07:00 | negative charge . So therefore it's attracted to the partially | |
| 07:04 | positive phosphorus atom . So oxygen is going to behave | |
| 07:09 | as a nuclear file attacking the phosphorus atom , causing | |
| 07:13 | one of the bromine atoms to be expelled . And | |
| 07:16 | so we're going to get an intermediate that looks like | |
| 07:18 | this . Mhm . Now , whenever oxygen has three | |
| 07:29 | bonds , it's going to have one lone pair and | |
| 07:32 | a positive charge . Now , if you recall predominated | |
| 07:39 | alcohols are highly acidic Whenever you have an oxygen with | |
| 07:45 | three bonds and the hydrogen on it , that hydrogen | |
| 07:51 | is going to be highly acidic . So what's going | |
| 07:53 | to happen next is an acid base reaction . So | |
| 08:00 | we're going to use the solvent paradyne to remove a | |
| 08:04 | hydrogen paradigm is a weak base . So paradigm is | |
| 08:16 | going to abstract a proton , putting these two electrons | |
| 08:20 | back on the oxygen . So this is what we | |
| 08:25 | have right now . Now , in the final step | |
| 08:35 | , a bromide ion is going to attack this carbon | |
| 08:40 | expel in this group . And so we're going to | |
| 08:44 | get one bruma butane as our product . And then | |
| 08:49 | this will be a side product which we can leave | |
| 08:52 | it like this . So that's the mechanism for the | |
| 08:55 | reaction of an alcohol with PBR three . This last | |
| 08:59 | step here is an S . And two step where | |
| 09:04 | we get inversion at the carbon atom . Now let's | |
| 09:08 | go over the mechanism of the other reaction . So | |
| 09:13 | let's start with our primary alcohol . I and let's | |
| 09:16 | react with vinyl chloride , which looks like this . | |
| 09:21 | It has a sulfur atom and oxygen to chlorine atoms | |
| 09:25 | . And the lone pair . Now the oxygen and | |
| 09:29 | chlorine atoms are more electro negative than sulfur . So | |
| 09:33 | the sulfur atom has a partial positive charge , just | |
| 09:36 | like the phosphorus atom . Now the oxygen is going | |
| 09:39 | to attack the sulfur , causing this pi bond and | |
| 09:42 | break . And so we're going to get this intermediate | |
| 09:57 | . So now the oxygen has a positive charge . | |
| 10:00 | And in the next step the oxygen is going to | |
| 10:05 | use one of its lone pairs to reform the pie | |
| 10:08 | bon , expelling a chlorine atom . Yeah . Mhm | |
| 10:21 | . So this is what we now have . What | |
| 10:26 | do you think is going to happen next ? Not | |
| 10:29 | typically this reaction is carried out in purity , and | |
| 10:34 | paradyne is a weak base which looks like this . | |
| 10:43 | And the purpose of paradigm in this example is to | |
| 10:47 | get rid of the hydrogen . In the last step | |
| 11:07 | , the chloride ion attacks from the back and then | |
| 11:11 | breaking the carbon oxygen bonds . Those electrons will be | |
| 11:14 | used to form a pi bond between a sulfur and | |
| 11:17 | the oxygen atom , and this will expel the chloride | |
| 11:20 | ion . And so we're going to get this product | |
| 11:25 | . So this will give us our alcohol chloride . | |
| 11:28 | We're also going to get sulfur dioxide which looks like | |
| 11:31 | this . The sulfur has a long period on it | |
| 11:35 | . So it causes the molecules have a bet shape | |
| 11:39 | and we have this other chlorate ion . And also | |
| 11:41 | paradigm has a hydrogen on it . And so that's | |
| 11:45 | how you can show the mechanism for the conversion of | |
| 11:48 | an alcohol into an alkali chloride used in S . | |
| 11:52 | O . C . L . Two in period . | |
| 11:53 | I mean now we need to discuss the stereo chemistry | |
| 11:59 | of these reactions . So let's say we have this | |
| 12:04 | particular alcohol to be , you know , and let's | |
| 12:07 | react it with hydroponic acid . What's going to happen | |
| 12:11 | ? So you need to know that this will occur | |
| 12:14 | by means of an S . M . On mechanism | |
| 12:15 | . Since we have a secondary alcohol . If we | |
| 12:18 | had a primary alcohol then it would be an essential | |
| 12:21 | reaction . But secondary and tertiary alcohols react with HBR | |
| 12:27 | By means of an s . and one mechanism . | |
| 12:30 | And so we're gonna get every cynic mixture of products | |
| 12:33 | . So the bromine atom , it could be on | |
| 12:35 | the dash or it can be on the wedge , | |
| 12:44 | but the key is we can get both stereo I | |
| 12:46 | summers in this example . Now let's say if we | |
| 12:50 | started with the same alcohol , but this time , | |
| 12:54 | instead of using H . B . I , We | |
| 12:56 | chose to use PBR three . What's going to happen | |
| 12:59 | now ? This reaction proceeds by an S and two | |
| 13:03 | mechanism . And so we're going to have an inversion | |
| 13:07 | at the configuration or at this uh carol center . | |
| 13:12 | So we're gonna have inversion of configuration and the broiling | |
| 13:16 | adam is going to be on the wedge as opposed | |
| 13:18 | to on the dash . So we only get one | |
| 13:21 | of the two stereo is immersed in this case . | |
| 13:26 | Mhm . Now if we use S . O . | |
| 13:29 | C . L . Two , something similar is going | |
| 13:31 | to happen . So if we use style no chloride | |
| 13:43 | , It's going to go through an sn two reaction | |
| 13:47 | . And so we're going to have an inversion at | |
| 13:50 | the Cairo center but we're going to get a chlorine | |
| 13:55 | atom instead of a broom in adam . So you | |
| 13:58 | need to be familiar with the steroid chemistry of these | |
| 14:01 | reactions . Another one you need to know is TSC | |
| 14:06 | our in case you see it on the test . | |
| 14:10 | Mhm . Now this one it works through retention but | |
| 14:15 | it converts the O . H into a good leaving | |
| 14:17 | group . And the product that you get is O | |
| 14:21 | . T . S . Which I'm going to talk | |
| 14:22 | about soon . So here we have an alcohol . | |
| 14:28 | And let's put the O . H . Group in | |
| 14:30 | the front attached to some our group . And then | |
| 14:35 | we have this compound which is pere it's Halloween . | |
| 14:44 | It's a final chloride , abbreviated T . S . | |
| 14:48 | C . O . And so to draw the product | |
| 14:52 | of this reaction , all you need to do is | |
| 14:55 | removed hydrochloric acid and simply connect these two groups together | |
| 15:09 | . And as you can see , you're going to | |
| 15:10 | get retention at the oxygen . So the stereo chemistry | |
| 15:15 | doesn't change mm . Now , for those of you | |
| 15:23 | who need the mechanism , here's how you can show | |
| 15:26 | it by the way . So this is T . | |
| 15:30 | S c . O . At the top , and | |
| 15:32 | this compound is known as our O . T . | |
| 15:37 | S . So we have an O T . S | |
| 15:39 | group attach to the our group . |
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