Alkene Redox Reactions: Crash Course Organic Chemistry #17 - By CrashCourse
Transcript
| 00:0-1 | You can review content from Crash course Organic Chemistry with | |
| 00:02 | the Crash course app available now for android and IOS | |
| 00:05 | devices . Hi , I'm Dave okay Chakravarty and welcome | |
| 00:08 | to Crash course organic chemistry oxidation , reduction reactions , | |
| 00:11 | also known as redox reactions are all around us from | |
| 00:16 | charging cell phone to avocados turning brown and they happen | |
| 00:19 | inside of us to redox reactions . Let us strip | |
| 00:22 | electrons off the food we eat and add them onto | |
| 00:25 | the oxygen we breathe to give us the energy we | |
| 00:27 | need to survive . Speaking of electrons in Crash course | |
| 00:30 | general chemistry we defined oxidation as the loss of electrons | |
| 00:34 | and reduction as the gain of electrons . Or as | |
| 00:37 | I remember it , leo the lion says Gert losing | |
| 00:40 | electrons , oxidation and gaining electrons is reduction . These | |
| 00:43 | rules are true for organic molecules but it can sometimes | |
| 00:46 | be easier to track the number of carbon oxygen bonds | |
| 00:49 | we gain or lose . For example , the molecule | |
| 00:51 | methane can be oxidized by replacing carbon hydrogen bonds with | |
| 00:55 | carbon oxygen bonds until we get carbon dioxide , the | |
| 00:58 | most oxidized form of a single carbon atoms . On | |
| 01:01 | the flip side , carbon dioxide can be reduced by | |
| 01:04 | replacing oxygen atoms or oxygen carbon bonds with hydrogen atoms | |
| 01:08 | . So we can also define oxidation is gaining bonds | |
| 01:11 | to oxygen and reduction as losing carbon oxygen bonds . | |
| 01:15 | In this episode , we'll consider the oxidation and reduction | |
| 01:18 | reactions of all kinds and see what types of oxygen | |
| 01:20 | containing compounds we can make from Calkins . Yeah , | |
| 01:34 | Oxidizing agents are molecules that oxidize organic compounds . They | |
| 01:38 | accept electrons from the organic compound and in the process | |
| 01:41 | three agents are reduced . Oxidizing agents are usually the | |
| 01:44 | culprits behind multiple carbon oxygen bonds forming from an alkaline | |
| 01:48 | . We'll see two types of oxidizing agents in this | |
| 01:50 | episode , ones with oxygen oxygen bonds and ones with | |
| 01:53 | metal oxygen bonds . Like we worked on last episode | |
| 01:56 | , a handy way to see patterns and predict products | |
| 01:58 | in addition reactions is by asking three key questions are | |
| 02:02 | three parts secret handshake question number one , what are | |
| 02:05 | we adding across the double bond question number two , | |
| 02:08 | where will the groups add on an asymmetrical molecule in | |
| 02:12 | general ? This question is asking about radio selectivity market | |
| 02:15 | because rule is an example of regio selectivity and question | |
| 02:19 | number three , what is the expected stereo chemistry of | |
| 02:21 | the added groups ? If they are added to the | |
| 02:23 | same face of the alkaline , it's Sin edition or | |
| 02:26 | if they're added to opposite faces , it's called Anti | |
| 02:29 | Edition in this episode , we'll look at these questions | |
| 02:31 | in the context of reactions that oxidize are alkaline friends | |
| 02:34 | . We saw an example of an oxidizing agent at | |
| 02:36 | the end of episode 16 with hydro operation oxidation . | |
| 02:40 | When hydrogen peroxide replace the boron atom we added to | |
| 02:43 | the al Qaim , we can also use peroxide to | |
| 02:45 | perform a reaction called iP oxidation and up oxide is | |
| 02:48 | a three member ID ring with an oxygen and we | |
| 02:50 | can make things from Calkins . So question number one | |
| 02:53 | is pretty straightforward approximation , adds one oxygen molecule across | |
| 02:58 | both atoms of the double bond . Usually we do | |
| 03:00 | approximation by reacting an alkaline with EM CPB , a | |
| 03:03 | medical or a peroxide Ben's OIC acid . You might | |
| 03:06 | see this reaction written out in a simplified way like | |
| 03:09 | this , but if you draw everything out , you | |
| 03:12 | can see how EM CPB A transfers one of its | |
| 03:14 | oxygen atoms in the process . To answer our other | |
| 03:17 | questions , we need to look at the reaction mechanism | |
| 03:20 | like hydro operation . We have another concerted reaction that | |
| 03:23 | happens all at once . So there's a lot of | |
| 03:25 | electron pushing to help us get to the transition state | |
| 03:28 | . In fact , if you can get this mechanism | |
| 03:30 | down , you'll be doing great . This reaction has | |
| 03:33 | some of the most complex aero pushing we'll see in | |
| 03:35 | a one step organic reaction basically the falcons double bond | |
| 03:39 | forms a strained bridge with the blue oxygen . At | |
| 03:42 | the same time . The other bonds break on EM | |
| 03:44 | CPB A . I'd like to start with the double | |
| 03:46 | bonded oxygen in EM CPB A and attack the proton | |
| 03:50 | . Then I can use the electrons from the oxygen | |
| 03:52 | hydrogen bond to attack the alki . The alkaline attacks | |
| 03:55 | back and the bonds of the blue oxygen that breaks | |
| 03:58 | forms a new carbon Neil . And the transition state | |
| 04:01 | looks like this because we're only adding one atom and | |
| 04:04 | its bridge . The answer to question two is it | |
| 04:06 | doesn't matter essentially the same group is added to each | |
| 04:10 | side and because everything is all attached at once in | |
| 04:12 | a concerted reaction . If we look at the stereo | |
| 04:15 | chemistry , we always have a sin edition . That's | |
| 04:17 | our answer to question three . The oxygen bridge can | |
| 04:20 | form on either side of the double bond . So | |
| 04:22 | we get to different in anti MERS as products and | |
| 04:24 | or ischemic mixture , which as you might remember , | |
| 04:27 | means equal amounts of each one . Overall approximation has | |
| 04:30 | a pretty straightforward combo . We can sum it up | |
| 04:33 | with another card , so now we know how to | |
| 04:36 | make it up oxide , which is a fun little | |
| 04:38 | ring shape . Earlier in this series , we looked | |
| 04:40 | at the bond energy of cyclo propane and learned that | |
| 04:42 | three member ID rings have a lot of strain so | |
| 04:45 | they're fairly unstable and instability means the chance for some | |
| 04:49 | exciting chemical reactions . Specifically , we can use up | |
| 04:52 | oxides as a gateway to anti die hydroxy elation . | |
| 04:55 | A name that hints at the stereo chemistry of this | |
| 04:58 | reaction . Spoiler alert , it's going to be anti | |
| 05:00 | edition . This name also hints at what we're going | |
| 05:03 | to end up with two hydroxyl groups also known as | |
| 05:06 | alcohol groups . Yes , hydroxyl and alcohol are interchangeable | |
| 05:11 | in case . Organic chemistry nomenclature wasn't tricky enough . | |
| 05:14 | The anti die hydroxy elation reaction happens the same way | |
| 05:16 | for both an anti members of an ip oxide . | |
| 05:18 | So we'll look at just one stereo . I seem | |
| 05:20 | to remember a strong acid in water forms hydro Nehemiah | |
| 05:23 | . So when we add a quiz hydrochloric acid to | |
| 05:26 | an ip oxide , the nuclear filic oxygen will attack | |
| 05:29 | our electro filic hydro Nehemiah , which makes a positively | |
| 05:32 | charged oxo Nehemiah . This next step is where it | |
| 05:35 | gets fun . A water molecule will swoop in as | |
| 05:37 | a nuclear file in an anti attack and open the | |
| 05:40 | app oxide . In this particular case , the water | |
| 05:42 | molecule can attack either of the a pox I'd carbons | |
| 05:45 | . The final step of a pox side opening is | |
| 05:47 | that typical 12 punch pattern that happens under acidic conditions | |
| 05:51 | . A water molecule ads first and the ac sodium | |
| 05:54 | ion we get is deep resonated by a second molecule | |
| 05:57 | of water . This makes the systemic mixture of 44 | |
| 06:00 | dimethyl cyclo hexane one to dial and that's it . | |
| 06:03 | Here's our three step summary of anti die hydroxy elation | |
| 06:07 | . The overall effect of the anti die hydroxy elation | |
| 06:10 | process is the addition of two alcohol groups on opposite | |
| 06:13 | sides of the substrate . But if we wanted to | |
| 06:15 | add them to the same side , we need a | |
| 06:17 | totally different reaction logically called Cindy hydroxy elation . And | |
| 06:21 | we actually have two options for oxidizing agents here , | |
| 06:24 | like fraternal twins . They're related but have some distinguishing | |
| 06:27 | features . One metal catalyst is Oz me um tetroxide | |
| 06:30 | , which is a wonderful source of oxygen but also | |
| 06:33 | super toxic . It's safer to use less of it | |
| 06:36 | so we can add other oxidizing agents , Leichter , | |
| 06:38 | bugle peroxide or end metal morphine and oxide , also | |
| 06:42 | known as an M . O . Into the reaction | |
| 06:44 | . Nomo helps remake osmium tetroxide over the reaction and | |
| 06:48 | lets us more safely use a catalytic amount of the | |
| 06:50 | toxic metal . The first step in this reaction is | |
| 06:53 | the formation of an oz made Esther , which is | |
| 06:55 | why our hydroxyl groups end up . Sin the Osmium | |
| 06:58 | regent approaches the double bond from one face . In | |
| 07:01 | the reduction step , the sodium by cell fight bonds | |
| 07:03 | to the Osmond Esther and helps it break apart in | |
| 07:05 | water . If we use osmium tetroxide with nemo , | |
| 07:08 | the animo does two things . It helps break up | |
| 07:11 | the Osmond Esther and gives up one of its oxygen's | |
| 07:14 | to regenerate osmium tetroxide , making the reaction catalytic in | |
| 07:18 | Oz me . Um The nitty gritty of these reactions | |
| 07:20 | is inorganic chemistry and a little beyond the scope of | |
| 07:22 | this series . What's most important for this one is | |
| 07:25 | which re agents to use for Cindy hydroxy elation and | |
| 07:28 | generally why they work so with that in mind . | |
| 07:31 | The other twin reaction happens in a similar way . | |
| 07:35 | The metal catalyst involved in the first oxidation step is | |
| 07:38 | potassium permanganate . And that second step needs cold basic | |
| 07:41 | conditions like sodium hydroxide floating around in an icy cold | |
| 07:44 | solution . And here's our card to sum up Cindy | |
| 07:47 | Hyde rocks elation up until this point we've been adding | |
| 07:50 | alcohol groups to falcons which is all fine and good | |
| 07:53 | . But it lacks some drama . Sure . All | |
| 07:56 | chemical reactions are cool in their own unique ways . | |
| 07:59 | But so far we've left our carbon chains intact . | |
| 08:01 | What about something that blasts the molecule into smaller pieces | |
| 08:05 | . Entropy turns out we can oxidize an alkaline and | |
| 08:07 | break the double bond completely . Using a reaction called | |
| 08:10 | those analysis , the name comes from our main region | |
| 08:13 | ozone and license , which is greek for breaking something | |
| 08:16 | down to understand how this happens . Let's look at | |
| 08:19 | the reaction mechanism . First step is R Tolkien reacting | |
| 08:21 | with ozone so it adds across the double bond . | |
| 08:24 | This makes an intermediate , which then breaks apart and | |
| 08:27 | rearranges into a molecule called ozone . I after we've | |
| 08:30 | gotten ozone I . The next step is a quick | |
| 08:32 | reduction reaction by adding D . M . S . | |
| 08:34 | Or zinc and acid . The referees that break up | |
| 08:36 | the reactant and our products are two different molecules each | |
| 08:40 | with the carbon Neil group . Now these products might | |
| 08:42 | be a little hard to visualize but we can think | |
| 08:44 | of those analysis as a pair of oxidizing scissors that | |
| 08:47 | snips the double bond in half while adding a double | |
| 08:49 | bonded oxygen to each side . On paper . I | |
| 08:52 | draw an alkaline and pencil . Use an eraser to | |
| 08:55 | snip the double bond in the center and then add | |
| 08:57 | in oxygen caps to both double bonded ends . Since | |
| 09:00 | for splitting the double bond in half an oz analysis | |
| 09:02 | , we don't need a no card . We don't | |
| 09:04 | need to worry about stereo chemistry and re geochemistry . | |
| 09:07 | Now we know lots of ways to oxidize Calkins and | |
| 09:09 | we also need to learn how to reduce them , | |
| 09:12 | adding hydrogen across the double bond is called hydrogenation and | |
| 09:16 | makes an al caine . However , the activation needed | |
| 09:18 | to get the party started is really high because other | |
| 09:21 | than the double bond , there aren't really any reactive | |
| 09:24 | sites in the alkaline or molecular hydrogen . They're pretty | |
| 09:27 | stable and boring as far as reactions go . So | |
| 09:30 | , to help a hydrogenation reaction along , we need | |
| 09:33 | a catalyst to lower the activation energy , usually a | |
| 09:36 | metal like platinum or palladium first the hydrogen forms a | |
| 09:39 | complex with the surface of the metal . The alcan | |
| 09:41 | approaches the metal hydrogen complex and hydrogen that's added with | |
| 09:45 | its electrons across the double bond , the alkaline gains | |
| 09:48 | electrons so it's reduced and the metal surface makes the | |
| 09:51 | hydrogen zad to one face a sin edition . Here's | |
| 09:55 | our hydrogenation note card . In the past few episodes | |
| 09:58 | , we've talked about a lot of different reactions involving | |
| 10:01 | al caine's building intuition about the products along the way | |
| 10:04 | . But let's face it in organic chemistry , we | |
| 10:07 | need tons of practice . One way of practicing is | |
| 10:09 | filling in a wheel of chemical reactions to see how | |
| 10:12 | they're all connected , basically taping all our reaction mechanisms | |
| 10:15 | together into one big map of the island of al | |
| 10:18 | keane's . You can pause the screen here if you | |
| 10:20 | want to take notes , here's the reaction wheel . | |
| 10:22 | Our team drew up with one metal cyclo hex one | |
| 10:25 | in in the centre . Look at all we've learned | |
| 10:27 | in the past few episodes alone and there's still so | |
| 10:30 | many more exciting things to come . But in this | |
| 10:32 | episode we learned about oxidation , the addition of oxygen | |
| 10:35 | and reduction , the addition of hydrogen in relation to | |
| 10:38 | organic molecules , added two alcohol groups to an AL | |
| 10:42 | king , both sin and anti . And used those | |
| 10:45 | analysis to cleave a double bond . All our reaction | |
| 10:47 | knowledge will keep building and we'll even see some familiar | |
| 10:50 | regents next time when we explore reduction reactions with all | |
| 10:53 | kinds . Thanks for watching this episode of Crash Course | |
| 10:55 | Organic Chemistry . If you want to help keep all | |
| 10:58 | Crash Course free for everybody forever , you can join | |
| 11:01 | our community on Patreon . Mhm . |
Summarizer
DESCRIPTION:
OVERVIEW:
Alkene Redox Reactions: Crash Course Organic Chemistry #17 is a free educational video by CrashCourse.
This page not only allows students and teachers view Alkene Redox Reactions: Crash Course Organic Chemistry #17 videos but also find engaging Sample Questions, Apps, Pins, Worksheets, Books related to the following topics.
GRADES:
STANDARDS:
