Radical Reactions & Hammond's Postulate: Crash Course Organic Chemistry #19 - By Math and Science
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 Debbie Chakravarty and welcome to | |
| 00:08 | Crash course organic chemistry antioxidants have gotten a lot of | |
| 00:12 | hype as a superfood , possibly helping us fight illnesses | |
| 00:14 | like heart disease and cancer . On a chemical level | |
| 00:18 | , antioxidants are fairly straightforward . They react with radicals | |
| 00:21 | which are molecules with a single unpaid electron . We | |
| 00:24 | need radicals to stay alive . They combine with oxygen | |
| 00:27 | as part of our normal metabolism . But sometimes these | |
| 00:30 | radical reactions produce too many reactive oxygen species or roos | |
| 00:34 | like the super oxide radical , it's not great to | |
| 00:37 | have too many chaotic roos around . So our bodies | |
| 00:40 | have ways to control them , like an enzyme that | |
| 00:43 | turns super oxide back into oxygen . But sometimes along | |
| 00:46 | the way , a more dangerous roos is produced . | |
| 00:49 | The hydroxyl radical can damage cell membranes , proteins and | |
| 00:52 | DNA . When our enzymes are overwhelmed , antioxidants can | |
| 00:56 | come to the rescue , giving up single electrons to | |
| 00:58 | neutralize cell damaging radicals . For example , vitamin C | |
| 01:02 | can donate a hydrogen with a single electron to neutralize | |
| 01:05 | roos . But nutrition isn't as simple as chugging gallons | |
| 01:09 | of green tea or blueberry smoothies to live a long | |
| 01:12 | life . Roos have a purpose signaling to ourselves that | |
| 01:15 | something is wrong . So the cell can correct it | |
| 01:18 | or die . Very high doses of antioxidants can overwhelm | |
| 01:21 | those natural signals that too much roos are being produced | |
| 01:24 | in the first place . So basically we need balance | |
| 01:28 | now that we know a little bit about neutralizing radicals | |
| 01:30 | . Let's learn how to make them and explore some | |
| 01:33 | of the reactions they perform . Mm Yeah . Yeah | |
| 01:44 | . Yeah . Yeah . So far in this series | |
| 01:47 | , we've talked a lot about pairs of electrons , | |
| 01:49 | there are lone pairs , shared pairs of electrons and | |
| 01:52 | covalin bonds and pushing pairs of electrons around . In | |
| 01:55 | reaction mechanisms , we've seen many examples of hetero politic | |
| 01:58 | cleavage where a bond breaks in a pair of electrons | |
| 02:01 | migrate to one of the two atoms , like when | |
| 02:03 | a bases reacted with the hydro nia . My on | |
| 02:05 | the two electrons from the O . H . Bond | |
| 02:07 | , both end up on the water molecule . But | |
| 02:10 | electrons don't always have a buddy . A radical is | |
| 02:13 | an atom or a group of atoms with a single | |
| 02:15 | compared electron . Some radicals are stable like the chemical | |
| 02:19 | nitric oxide , which ends up with a radical on | |
| 02:21 | nitrogen radicals can also form during chemical reactions and make | |
| 02:25 | some interesting stuff happen . Like the reactive oxygen species | |
| 02:28 | we were just talking about this process is called hemolytic | |
| 02:31 | cleavage where electrons and a broken bond go and equal | |
| 02:34 | but different directions forming two radicals . For example , | |
| 02:38 | with heater light , the bond and die atomic chlorine | |
| 02:40 | is weak enough to be split equally between the two | |
| 02:42 | chlorine atoms , with each one getting a single electron | |
| 02:46 | . Instead of using a full arrowhead to push the | |
| 02:48 | pair of electrons , we use half barbed arrows to | |
| 02:51 | split the bond , pushing single electrons onto each chlorine | |
| 02:54 | atom . We're finally using those fish Lecaros . We | |
| 02:57 | talked about an episode 13 radical reactions take place in | |
| 03:00 | three stages initiation propagation and termination . The initiation stages | |
| 03:05 | where a reactive radical forms . We need this reaction | |
| 03:08 | to get the party started . Like the first person | |
| 03:10 | who breaks the ice and starts dancing their heart out | |
| 03:13 | propagation is where a few radicals bounce around reacting with | |
| 03:16 | other molecules . It's the step that keeps people on | |
| 03:20 | the dance floor but it's sort of important to limit | |
| 03:22 | the number of high energy guests so things don't get | |
| 03:25 | too rowdy . Importantly , propagation also regenerates the reactive | |
| 03:28 | radical we made in the initiation step . Finally , | |
| 03:31 | the termination stage is when the radical reaction stops . | |
| 03:35 | We've had enough high energy dancing . It's time to | |
| 03:37 | end the party so everyone can go to sleep talking | |
| 03:40 | metaphorically about radical reactions and parties might be fun . | |
| 03:43 | But actually looking at examples will help us get more | |
| 03:46 | comfortable with them to start . Let's look at the | |
| 03:48 | radical halogen nation of al canes to keep things simple | |
| 03:51 | , will use methane as our al Kane . The | |
| 03:53 | thing that's going to be radically how originated Like the | |
| 03:56 | name of the reaction our initiation step makes chlorine radicals | |
| 03:59 | are high energy party people . The propagation stage kicks | |
| 04:02 | off when a chlorine radical bumps into a methane molecule | |
| 04:05 | . We can think of the chlorine radical as being | |
| 04:07 | so charismatic that a hydrogen electron wants to party to | |
| 04:10 | or in reaction terms mega bond . The hydrogen only | |
| 04:14 | needs to donate one of its two shared electrons to | |
| 04:16 | make a bond and form hydrochloric acid . So as | |
| 04:20 | a result , a metal radical forms with a single | |
| 04:22 | electron on the carbon sitting happily in a p orbital | |
| 04:25 | . Then this metal radical can react with di atomic | |
| 04:28 | chlorine to make Clara methane plus another chlorine radical , | |
| 04:32 | which can continue the propagation stage by reacting with another | |
| 04:35 | molecule of methane , generating a new chlorine radical . | |
| 04:38 | The steps of the chain reaction repeat and the dance | |
| 04:41 | party rages on Eventually . Most of our regions are | |
| 04:44 | used up and it's time to get all the high | |
| 04:45 | energy radicals out of here . So we enter the | |
| 04:48 | termination stage basically to radicals make a bond using their | |
| 04:52 | single electrons . All radicals are used up and the | |
| 04:55 | party is officially over here . There are three possible | |
| 04:58 | termination steps . We can end with two chlorine radicals | |
| 05:01 | or instead one metal radical and one chlorine radical . | |
| 05:04 | Or two methyl radicals can combine radical reactions happen quickly | |
| 05:09 | and can create side products like how to metal radicals | |
| 05:12 | can make ethane when we're trying to make chloral methane | |
| 05:14 | . And there are some patterns in radical reactivity that | |
| 05:17 | we might recognize from other organic reactions . First of | |
| 05:20 | all , more substitution makes a radical more stable . | |
| 05:23 | We've learned that tertiary carbo Canadians are the most stable | |
| 05:26 | carbo cat ions and tertiary radicals are the most stable | |
| 05:30 | radicals to . So for example , if we do | |
| 05:32 | radical brahman ation of propane , we can create a | |
| 05:34 | primary or secondary radical because the secondary radical is more | |
| 05:38 | stable . We get way more of the product that | |
| 05:41 | comes from it to Bmo propane . But here's the | |
| 05:43 | weird thing if we do radical chlorination of propane , | |
| 05:47 | it's much closer to a 50 50 split of the | |
| 05:49 | primary and secondary Clara propane products . Even though we | |
| 05:52 | still see more to clara propane to explain why bromine | |
| 05:56 | radicals and chlorine radicals act so differently . Even though | |
| 05:59 | they follow the same general pattern will need to revisit | |
| 06:02 | thermodynamics . The big difference between these two reactions is | |
| 06:05 | that the first propagation step in the radical chlorination of | |
| 06:07 | propane is eggs . A thermic , which means it | |
| 06:10 | loses heat to the surroundings like a chemical hot pack | |
| 06:13 | . On the other hand , the first propagation step | |
| 06:15 | in the radical domination of propane is end A thermic | |
| 06:18 | , which means the reaction takes in energy from its | |
| 06:20 | surroundings like a chemical cold pack . We need to | |
| 06:23 | look closely at the transition state of these reactions . | |
| 06:26 | The peak of the hill on an energy diagram or | |
| 06:28 | bonds are partially formed . Hammond's postulate is the idea | |
| 06:31 | that the transition state of reaction resembles the species . | |
| 06:34 | It's closest to an energy . In other words , | |
| 06:37 | the transition state for an exo thermic reaction will look | |
| 06:40 | more like the reactant while the transition state for an | |
| 06:43 | end to thermic reaction will look more like the products | |
| 06:46 | . So in the first propagation step of radical chlorination | |
| 06:48 | , which is X . A . Thermic , the | |
| 06:50 | transition state looks a lot like the reactant and happens | |
| 06:53 | earlier along the reaction path . It doesn't matter too | |
| 06:56 | much that the secondary radical is more stable than the | |
| 06:58 | primary one . Because the transition state doesn't resemble the | |
| 07:01 | propel radical that much now are chlorine radical doesn't just | |
| 07:04 | pull off the first hydrogen it collides with on propane | |
| 07:07 | . The formation of the secondary propel radical is slightly | |
| 07:10 | favored because the activation energy is just a little lower | |
| 07:14 | , but plenty of primary and secondary radicals go on | |
| 07:17 | to make the final products . But in the first | |
| 07:19 | propagation step of radical domination , which is end a | |
| 07:21 | thermic , the transition state happens later in the reaction | |
| 07:25 | and resembles appropriate radical much more . in this late | |
| 07:28 | transition state , the secondary carbon radical has a significantly | |
| 07:31 | lower peak to overcome its activation energy . So much | |
| 07:35 | more of the secondary propel radical forms and goes on | |
| 07:37 | to make the major product . We've talked about the | |
| 07:40 | differences . But one key thing these reactions have in | |
| 07:42 | common is taking our couch , potato al canes and | |
| 07:45 | adding reactive groups onto them . This is so important | |
| 07:49 | to involve them in more exciting organic chemistry . So | |
| 07:52 | with alcan's covered , let's move on . Like we | |
| 07:54 | saw what super oxide and antioxidants radical reactions can be | |
| 07:58 | in compounds with double bonds to for example the olympic | |
| 08:01 | domination of al Hakim's . This is a more carefully | |
| 08:05 | planned party . Under the right conditions , all kinds | |
| 08:07 | can be brominated at the carbon next to the double | |
| 08:10 | bond , which is called the olympic position . As | |
| 08:12 | with all radical reactions . The first stage is initiation | |
| 08:16 | . We need a bro mean radical to make one | |
| 08:19 | will take a bro ming containing source called N bro | |
| 08:21 | Mossack cinema or NBS for short and irradiated with light | |
| 08:26 | . This what's the molecule into radicals . And some | |
| 08:28 | of these radicals form a small amount of molecular bro | |
| 08:31 | . Ming . An energetic grooming radical is irresistible to | |
| 08:34 | Angelique hydrogen electron on cyclo heck scene . So the | |
| 08:37 | stage is set for propagation . HBR is formed in | |
| 08:40 | an aloe radical is left on the alkaline , basically | |
| 08:43 | a lilic hydrogen are so ready to party because this | |
| 08:46 | al radical is in a p orbital and is stabilized | |
| 08:49 | by residents with a double bond resonance stabilization and radicals | |
| 08:52 | is super important . In fact . The extensive resonance | |
| 08:55 | stabilization in the radical anti and formed from vitamin C | |
| 08:59 | . Is partially why it's such a good antioxidant . | |
| 09:01 | Anyway to go back to a little abomination , the | |
| 09:03 | propagation stage continues as the a little radical reacts with | |
| 09:07 | the small amounts of molecular bro ming we formed even | |
| 09:10 | though we have an alkaline and molecular bro ming which | |
| 09:12 | are ingredients in the addition reactions we've learned in the | |
| 09:15 | past few episodes . The radical propagation steps are really | |
| 09:19 | fast so they take control . The radical reaction keeps | |
| 09:22 | propagating until the re agents are all used up and | |
| 09:25 | all the radicals pair up , terminating the party . | |
| 09:27 | Now we've seen al canes and Calkins , but we | |
| 09:30 | can't forget about all kinds specifically , the dissolving metal | |
| 09:33 | reduction reaction produces e Elkins from all kinds . The | |
| 09:37 | dissolving metal part of the name comes from to re | |
| 09:40 | agents that you can see above the reaction arrow sodium | |
| 09:43 | metal dissolved in liquid ammonia to produce solve ated electrons | |
| 09:46 | that are floating around and stabilized by the ammonia solvent | |
| 09:50 | . These solve ated electrons form a beautiful dark blue | |
| 09:53 | solution . Will actually talk about colors in organic chemistry | |
| 09:56 | much later in the series . So this is just | |
| 09:58 | a sneak peek for now we'll focus on how salivated | |
| 10:01 | electrons do radical reactions . It's a little tricky . | |
| 10:04 | So we'll use a reaction mechanism diagram with orbital's to | |
| 10:07 | really see what's happening . To kick off the reaction | |
| 10:10 | . A salivated electron can jump into one of the | |
| 10:12 | plain old p orbital's of a pi bond in the | |
| 10:14 | AL kind . As the bonhomme politically cleaves the solve | |
| 10:18 | ated electron pairs up with one electron from the triple | |
| 10:21 | bond . So now we have a new molecule . | |
| 10:23 | The new electron pair causes one carbon to have a | |
| 10:25 | negative charge since it has five valence electrons . Meanwhile | |
| 10:29 | the other electron from the triple bond forms a radical | |
| 10:32 | on the other carbon one . This very basic and | |
| 10:35 | I . And finds a source of protons like the | |
| 10:37 | ammonia floating around the negative charge , will actually remove | |
| 10:40 | a proton from ammonia in an acid base reaction . | |
| 10:43 | To finish this reaction , another salivated electron comes along | |
| 10:47 | adds to the orbital holding that radical and makes another | |
| 10:49 | negative charge , putting five valence electrons on the formally | |
| 10:53 | radical carbon . At this point , the our group's | |
| 10:55 | reorganize themselves to different sides of the double bond to | |
| 10:58 | make a more stable an ion . Finally , another | |
| 11:01 | molecule of ammonia is deep resonated and we get an | |
| 11:03 | E alkaline and the party can end . Even though | |
| 11:06 | we explored antioxidants to solve ated electrons , we didn't | |
| 11:09 | even get to how radicals help us make different kinds | |
| 11:12 | of plastics . So don't worry , this won't be | |
| 11:14 | the last time we hear of them in this episode | |
| 11:16 | . We learn that radicals are highly reactive single electron | |
| 11:20 | species , which are important in antioxidant chemistry . There | |
| 11:23 | are three steps in radical reactions , initiation propagation and | |
| 11:27 | termination . Hammond's postulate helps us predict transition states and | |
| 11:30 | explain product distributions . And radical reactions can be used | |
| 11:35 | to halogen al canes and al keens and reduce all | |
| 11:38 | kinds in the next episode of crash course organic chemistry | |
| 11:41 | will use these halogen It'd all canes in a new | |
| 11:43 | type of reaction substitution . Thanks for watching this episode | |
| 11:47 | of Crash course Organic chemistry . If you want to | |
| 11:49 | help keep all crash course free for everybody forever . | |
| 11:52 | You can join our community on Patreon . |
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