Hey guys. In this video, we're going to talk about a really important synthetic pathway called the Curtius rearrangement. This reaction does go by another name. It's also called the reduction of acyl azide. That name really describes what's going on here. An acyl azide is a functional group that has a carbonyl, an R group and then N3 on one side. That's an azide. If you can reduce this molecule and get the carbonyl to come off, what we're going to wind up getting is we're going to wind up getting a primary amine. This is going to require a really interesting rearrangement for that to take place. There are only 2 reagents in this reaction. There's heat and there's water. You might think that it's a really easy mechanism, but actually, it's really strange because of the fact that atoms are rearranging and we're going to have a reactive intermediate called a nitrene that isn't really commonly seen in orgo. We're going to definitely make sure to handle that in the mechanism part. What are the 2 steps? The first step is heat. Heat is going to drive the rearrangement of this molecule here into isocyanate. Now isocyanate is its own topic within organic chemistry. There are a lot of reactions that we can do with isocyanate. But for right now, this is just going to be the middle structure that we use, the intermediate structure that we then react with again to get our primary amine. What's our second step? Our second step is the addition of water to that isocyanate. That's going to result in a decarboxylation reaction and it's going to liberate 2 gases at the end. It's going to liberate CO2 gas because decarboxylation reactions always liberate CO2 gas and we're also going to liberate N2 gas from the decomposition of the acyl azide in the first step. Now I have mentioned a few terms here. For example, decarboxylation. That's a mechanism that I teach in a separate video. If you want to know more about what a decarboxylation reaction is, you can always just type it into the Klutch search bar and you'll find that video. That being said, let's go ahead and just dive into this mechanism and see what it's all about. I already showed you guys what an acyl azide looks like. When you draw it out in bond line structure, this is what you're going to get. That's the most common way that it's represented. It's N double bond N double bond N and with the formal charges accordingly. But guys, this azide has a resonance structure, and that resonance structure has to be taken into account. That resonance structure would be that the negative charge could make a triple bond. That would already have 3 bonds on one side. That means I only need 1 more bond on the other, or I'd be violating the octet. If I make this bond, I'm going to break this bond and form a lone pair on that nitrogen. That means that the resonance structure on the other side looks something like this. I've got a triple bond here, a negative charge here because I added an extra lone pair, and I still have a positive in the middle because it still has 4 bonds. Nothing changed for that middle nitrogen. What's interesting here guys is that usually, these resonance structures both exist. They're both averaging into the hybrid. But in the presence of heat, one of these resonance structures is going to influence the character of the molecule more than the other. The reason is that we can have a decomposition reaction. Heat is going to make this decompose. And the reason is that this resonance structure, the second one, looks a whole lot like N2 gas. N2 gas is just N triple bond N and it composes 78% of the atmosphere. If 78% of the atmosphere is N2 gas, do you think it's stable or unstable? It's highly stable, guys. I mean you're breathing it in constantly. It's not reacting with you, is it? Or not too much. This is a very stable entity. And if you can become N2 gas, you're like in chemical Nirvana. That's like the best thing you can do. Look at this resonance structure. It's one bond away from being N2 gas. In heat, what you're going to get is a decomposition reaction where these electrons pick up and leave as a lone pair. What you wind up getting is now your n with just 2 lone pairs and nothing else, R plus your N2 gas. This molecule product, it's really an intermediate because it has the right number of valence electrons. Remember that nitrogen wants to have 5? It has 5. But this is highly reactive because it's not filling its octet. This nitrogen only has 6 octet electrons. If you were to count, lone pair is 2, lone pair is 2, the bond is 2, that's 6. We need 8. This is a very reactive intermediate called a nitrene. It turns out this nitrene is going to want to rearrange. This is the Curtius rearrangement part. What we're going to get is that the R group, the electrons from the R group actually attach to the N. A lone pair comes down and forms a double bond. This is just going to be our rearrangement. And what we wind up getting is our isocyanate as a product. I'm going to have O double bond C, double bond N with now an R group coming off of it. This is a molecule called isocyanate, which as I alluded to earlier, is actually a really important molecule in organic chemistry. There are a lot of different addition reactions we can do to this. But for this mechanism, we're only going to do 1 and that's going to be the addition of water. You could end this here. If all you did was you added heat to an acyl azide, you'd get isocyanate and you'd be done. But we want to get a primary amine. Essentially, we want to liberate this part. All we want is the NR component. We don't want the carbon. We don't want the O. How can we get rid of that if we add water? In my second step, I add water. Can you guys predict which atom the water will be most attracted to in a nucleophilic attack? What do you guys think? You got it. We're going to attack the carbon, carbonyl carbon. We're going to push the electrons down to the end. What this is going to give us is a molecule that looks like this. OHNR, and eventually, this is going to get an H because it's going to form a negative charge and it's going to protonate. This is called Carbamic acid. What's special about carbamic acid is that it is very unstable. It's not a stable molecule, so it can spontaneously decarboxylate. Now again, for more on the mechanism of decarboxylation, search that topic individually. But we'll just draw it as it relates to this molecule here. This is going to be our decarboxylation. What we're going to do is that the nitrogen, let me actually draw this H sticking out so it's going to be easier. This nitrogen grabs the H. Make a bond. Break a bond. We're going to take the electrons from this single bond and donate them to the bond between the O and the C. Now that that carbon has 4 bonds, the carbonyl carbon, we're going to use these electrons to make a lone pair on the end. It's a weird reaction. But notice what you get at the end. What you're going to get is now a nitrogen with an R group with how many H's? 2. You've got the original H, and we've got the new H that we grabbed. What else do we have? Well, we also have carbon with now a double bond O and a double bond O. Do you guys know what that is? The product of a decarboxylation is always CO2 gas. We just created 2 different gases. One of them is a greenhouse gas. Oh no. Hurting the environment. Hopefully it's you know, we're keeping it in the lab though. Guys, this is really interesting. We've just made CO2 gas. We've made N2 gas here and here. But most importantly and what your professors will be most interested in is that we made a primary amine. That primary amine also lost a carbon. This is going to be an interesting synthetic reaction that we use when we're trying to get an amine and we're trying to lose a carbon. I'll show you guys why you would want to use that in a second. This is a really great reaction to use. It looks complicated, but it's actually used more often than you think in organic chemistry. That being said, that’s the whole mechanism. I hope that made sense. Let's go ahead and look.
- 1. A Review of General Chemistry5h 5m
- Summary23m
- Intro to Organic Chemistry5m
- Atomic Structure16m
- Wave Function9m
- Molecular Orbitals17m
- Sigma and Pi Bonds9m
- Octet Rule12m
- Bonding Preferences12m
- Formal Charges6m
- Skeletal Structure14m
- Lewis Structure20m
- Condensed Structural Formula15m
- Degrees of Unsaturation15m
- Constitutional Isomers14m
- Resonance Structures46m
- Hybridization23m
- Molecular Geometry16m
- Electronegativity22m
- 2. Molecular Representations1h 14m
- 3. Acids and Bases2h 46m
- 4. Alkanes and Cycloalkanes4h 19m
- IUPAC Naming29m
- Alkyl Groups13m
- Naming Cycloalkanes10m
- Naming Bicyclic Compounds10m
- Naming Alkyl Halides7m
- Naming Alkenes3m
- Naming Alcohols8m
- Naming Amines15m
- Cis vs Trans21m
- Conformational Isomers13m
- Newman Projections14m
- Drawing Newman Projections16m
- Barrier To Rotation7m
- Ring Strain8m
- Axial vs Equatorial7m
- Cis vs Trans Conformations4m
- Equatorial Preference14m
- Chair Flip9m
- Calculating Energy Difference Between Chair Conformations17m
- A-Values17m
- Decalin7m
- 5. Chirality3h 39m
- Constitutional Isomers vs. Stereoisomers9m
- Chirality12m
- Test 1:Plane of Symmetry7m
- Test 2:Stereocenter Test17m
- R and S Configuration43m
- Enantiomers vs. Diastereomers13m
- Atropisomers9m
- Meso Compound12m
- Test 3:Disubstituted Cycloalkanes13m
- What is the Relationship Between Isomers?16m
- Fischer Projection10m
- R and S of Fischer Projections7m
- Optical Activity5m
- Enantiomeric Excess20m
- Calculations with Enantiomeric Percentages11m
- Non-Carbon Chiral Centers8m
- 6. Thermodynamics and Kinetics1h 22m
- 7. Substitution Reactions1h 48m
- 8. Elimination Reactions2h 30m
- 9. Alkenes and Alkynes2h 9m
- 10. Addition Reactions3h 18m
- Addition Reaction6m
- Markovnikov5m
- Hydrohalogenation6m
- Acid-Catalyzed Hydration17m
- Oxymercuration15m
- Hydroboration26m
- Hydrogenation6m
- Halogenation6m
- Halohydrin12m
- Carbene12m
- Epoxidation8m
- Epoxide Reactions9m
- Dihydroxylation8m
- Ozonolysis7m
- Ozonolysis Full Mechanism24m
- Oxidative Cleavage3m
- Alkyne Oxidative Cleavage6m
- Alkyne Hydrohalogenation3m
- Alkyne Halogenation2m
- Alkyne Hydration6m
- Alkyne Hydroboration2m
- 11. Radical Reactions1h 58m
- 12. Alcohols, Ethers, Epoxides and Thiols2h 42m
- Alcohol Nomenclature4m
- Naming Ethers6m
- Naming Epoxides18m
- Naming Thiols11m
- Alcohol Synthesis7m
- Leaving Group Conversions - Using HX11m
- Leaving Group Conversions - SOCl2 and PBr313m
- Leaving Group Conversions - Sulfonyl Chlorides7m
- Leaving Group Conversions Summary4m
- Williamson Ether Synthesis3m
- Making Ethers - Alkoxymercuration4m
- Making Ethers - Alcohol Condensation4m
- Making Ethers - Acid-Catalyzed Alkoxylation4m
- Making Ethers - Cumulative Practice10m
- Ether Cleavage8m
- Alcohol Protecting Groups3m
- t-Butyl Ether Protecting Groups5m
- Silyl Ether Protecting Groups10m
- Sharpless Epoxidation9m
- Thiol Reactions6m
- Sulfide Oxidation4m
- 13. Alcohols and Carbonyl Compounds2h 17m
- 14. Synthetic Techniques1h 26m
- 15. Analytical Techniques:IR, NMR, Mass Spect7h 3m
- Purpose of Analytical Techniques5m
- Infrared Spectroscopy16m
- Infrared Spectroscopy Table31m
- IR Spect:Drawing Spectra40m
- IR Spect:Extra Practice26m
- NMR Spectroscopy10m
- 1H NMR:Number of Signals26m
- 1H NMR:Q-Test26m
- 1H NMR:E/Z Diastereoisomerism8m
- H NMR Table24m
- 1H NMR:Spin-Splitting (N + 1) Rule22m
- 1H NMR:Spin-Splitting Simple Tree Diagrams11m
- 1H NMR:Spin-Splitting Complex Tree Diagrams12m
- 1H NMR:Spin-Splitting Patterns8m
- NMR Integration18m
- NMR Practice14m
- Carbon NMR4m
- Structure Determination without Mass Spect47m
- Mass Spectrometry12m
- Mass Spect:Fragmentation28m
- Mass Spect:Isotopes27m
- 16. Conjugated Systems6h 13m
- Conjugation Chemistry13m
- Stability of Conjugated Intermediates4m
- Allylic Halogenation12m
- Reactions at the Allylic Position39m
- Conjugated Hydrohalogenation (1,2 vs 1,4 addition)26m
- Diels-Alder Reaction9m
- Diels-Alder Forming Bridged Products11m
- Diels-Alder Retrosynthesis8m
- Molecular Orbital Theory9m
- Drawing Atomic Orbitals6m
- Drawing Molecular Orbitals17m
- HOMO LUMO4m
- Orbital Diagram:3-atoms- Allylic Ions13m
- Orbital Diagram:4-atoms- 1,3-butadiene11m
- Orbital Diagram:5-atoms- Allylic Ions10m
- Orbital Diagram:6-atoms- 1,3,5-hexatriene13m
- Orbital Diagram:Excited States4m
- Pericyclic Reaction10m
- Thermal Cycloaddition Reactions26m
- Photochemical Cycloaddition Reactions26m
- Thermal Electrocyclic Reactions14m
- Photochemical Electrocyclic Reactions10m
- Cumulative Electrocyclic Problems25m
- Sigmatropic Rearrangement17m
- Cope Rearrangement9m
- Claisen Rearrangement15m
- 17. Ultraviolet Spectroscopy51m
- 18. Aromaticity2h 34m
- 19. Reactions of Aromatics: EAS and Beyond5h 1m
- Electrophilic Aromatic Substitution9m
- Benzene Reactions11m
- EAS:Halogenation Mechanism6m
- EAS:Nitration Mechanism9m
- EAS:Friedel-Crafts Alkylation Mechanism6m
- EAS:Friedel-Crafts Acylation Mechanism5m
- EAS:Any Carbocation Mechanism7m
- Electron Withdrawing Groups22m
- EAS:Ortho vs. Para Positions4m
- Acylation of Aniline9m
- Limitations of Friedel-Crafts Alkyation19m
- Advantages of Friedel-Crafts Acylation6m
- Blocking Groups - Sulfonic Acid12m
- EAS:Synergistic and Competitive Groups13m
- Side-Chain Halogenation6m
- Side-Chain Oxidation4m
- Reactions at Benzylic Positions31m
- Birch Reduction10m
- EAS:Sequence Groups4m
- EAS:Retrosynthesis29m
- Diazo Replacement Reactions6m
- Diazo Sequence Groups5m
- Diazo Retrosynthesis13m
- Nucleophilic Aromatic Substitution28m
- Benzyne16m
- 20. Phenols55m
- 21. Aldehydes and Ketones: Nucleophilic Addition4h 56m
- Naming Aldehydes8m
- Naming Ketones7m
- Oxidizing and Reducing Agents9m
- Oxidation of Alcohols28m
- Ozonolysis7m
- DIBAL5m
- Alkyne Hydration9m
- Nucleophilic Addition8m
- Cyanohydrin11m
- Organometallics on Ketones19m
- Overview of Nucleophilic Addition of Solvents13m
- Hydrates6m
- Hemiacetal9m
- Acetal12m
- Acetal Protecting Group16m
- Thioacetal6m
- Imine vs Enamine15m
- Addition of Amine Derivatives5m
- Wolff Kishner Reduction7m
- Baeyer-Villiger Oxidation39m
- Acid Chloride to Ketone7m
- Nitrile to Ketone9m
- Wittig Reaction18m
- Ketone and Aldehyde Synthesis Reactions14m
- 22. Carboxylic Acid Derivatives: NAS2h 51m
- Carboxylic Acid Derivatives7m
- Naming Carboxylic Acids9m
- Diacid Nomenclature6m
- Naming Esters5m
- Naming Nitriles3m
- Acid Chloride Nomenclature5m
- Naming Anhydrides7m
- Naming Amides5m
- Nucleophilic Acyl Substitution18m
- Carboxylic Acid to Acid Chloride6m
- Fischer Esterification5m
- Acid-Catalyzed Ester Hydrolysis4m
- Saponification3m
- Transesterification5m
- Lactones, Lactams and Cyclization Reactions10m
- Carboxylation5m
- Decarboxylation Mechanism14m
- Review of Nitriles46m
- 23. The Chemistry of Thioesters, Phophate Ester and Phosphate Anhydrides1h 10m
- 24. Enolate Chemistry: Reactions at the Alpha-Carbon1h 53m
- Tautomerization9m
- Tautomers of Dicarbonyl Compounds6m
- Enolate4m
- Acid-Catalyzed Alpha-Halogentation4m
- Base-Catalyzed Alpha-Halogentation3m
- Haloform Reaction8m
- Hell-Volhard-Zelinski Reaction3m
- Overview of Alpha-Alkylations and Acylations5m
- Enolate Alkylation and Acylation12m
- Enamine Alkylation and Acylation16m
- Beta-Dicarbonyl Synthesis Pathway7m
- Acetoacetic Ester Synthesis13m
- Malonic Ester Synthesis15m
- 25. Condensation Chemistry2h 9m
- 26. Amines1h 43m
- 27. Heterocycles2h 0m
- Nomenclature of Heterocycles15m
- Acid-Base Properties of Nitrogen Heterocycles10m
- Reactions of Pyrrole, Furan, and Thiophene13m
- Directing Effects in Substituted Pyrroles, Furans, and Thiophenes16m
- Addition Reactions of Furan8m
- EAS Reactions of Pyridine17m
- SNAr Reactions of Pyridine18m
- Side-Chain Reactions of Substituted Pyridines20m
- 28. Carbohydrates5h 53m
- Monosaccharide20m
- Monosaccharides - D and L Isomerism9m
- Monosaccharides - Drawing Fischer Projections18m
- Monosaccharides - Common Structures6m
- Monosaccharides - Forming Cyclic Hemiacetals12m
- Monosaccharides - Cyclization18m
- Monosaccharides - Haworth Projections13m
- Mutarotation11m
- Epimerization9m
- Monosaccharides - Aldose-Ketose Rearrangement8m
- Monosaccharides - Alkylation10m
- Monosaccharides - Acylation7m
- Glycoside6m
- Monosaccharides - N-Glycosides18m
- Monosaccharides - Reduction (Alditols)12m
- Monosaccharides - Weak Oxidation (Aldonic Acid)7m
- Reducing Sugars23m
- Monosaccharides - Strong Oxidation (Aldaric Acid)11m
- Monosaccharides - Oxidative Cleavage27m
- Monosaccharides - Osazones10m
- Monosaccharides - Kiliani-Fischer23m
- Monosaccharides - Wohl Degradation12m
- Monosaccharides - Ruff Degradation12m
- Disaccharide30m
- Polysaccharide11m
- 29. Amino Acids3h 20m
- Proteins and Amino Acids19m
- L and D Amino Acids14m
- Polar Amino Acids14m
- Amino Acid Chart18m
- Acid-Base Properties of Amino Acids33m
- Isoelectric Point14m
- Amino Acid Synthesis: HVZ Method12m
- Synthesis of Amino Acids: Acetamidomalonic Ester Synthesis16m
- Synthesis of Amino Acids: N-Phthalimidomalonic Ester Synthesis13m
- Synthesis of Amino Acids: Strecker Synthesis13m
- Reactions of Amino Acids: Esterification7m
- Reactions of Amino Acids: Acylation3m
- Reactions of Amino Acids: Hydrogenolysis6m
- Reactions of Amino Acids: Ninhydrin Test11m
- 30. Peptides and Proteins2h 42m
- Peptides12m
- Primary Protein Structure4m
- Secondary Protein Structure17m
- Tertiary Protein Structure11m
- Disulfide Bonds17m
- Quaternary Protein Structure10m
- Summary of Protein Structure7m
- Intro to Peptide Sequencing2m
- Peptide Sequencing: Partial Hydrolysis25m
- Peptide Sequencing: Partial Hydrolysis with Cyanogen Bromide7m
- Peptide Sequencing: Edman Degradation28m
- Merrifield Solid-Phase Peptide Synthesis18m
- 32. Lipids 2h 50m
- 34. Nucleic Acids1h 32m
- 35. Transition Metals5h 33m
- Electron Configuration of Elements45m
- Coordination Complexes20m
- Ligands24m
- Electron Counting10m
- The 18 and 16 Electron Rule13m
- Cross-Coupling General Reactions40m
- Heck Reaction40m
- Stille Reaction13m
- Suzuki Reaction25m
- Sonogashira Coupling Reaction17m
- Fukuyama Coupling Reaction15m
- Kumada Coupling Reaction13m
- Negishi Coupling Reaction16m
- Buchwald-Hartwig Amination Reaction19m
- Eglinton Reaction17m
Curtius Rearrangement - Online Tutor, Practice Problems & Exam Prep
The Curtius rearrangement is a synthetic pathway that transforms acyl azides into primary amines through a two-step process involving heat and water. Initially, heat induces the formation of isocyanate from the acyl azide, a reactive intermediate. The subsequent addition of water leads to the formation of carbamic acid, which undergoes decarboxylation, releasing CO2 and N2 gases. This reaction is significant in organic synthesis for generating amines while eliminating a carbon atom, showcasing the utility of isocyanates in various organic reactions.
General Mechanism
Video transcript
Propose a Synthesis
Video transcript
Right, guys. Maybe you didn't know it, and that's okay. But what I do want to emphasize here is that this pathway that I'm showing you is one of the more important pathways for aromatic synthesis and it's one of the fastest ways that you can make aniline because if you recall, I've never taught you an EAS mechanism for aniline. We have to get creative when we want to make it. The first thing you'd do is you'd add an R group. That was already done for you. We already have an R group there. If you wanted to add an R group, hopefully you could remember some reactions that you could use to add R groups. For example, Friedel Crafts alkylation. But now that the R group is there, what can we do? We want to turn this into an acyl azide to rearrange. The first step to doing that would be a carboxylic acid. Let's go ahead and do a side chain oxidation with KMnO4. Now I'm already noticing I'm going to run out of room in this box because KMnO4, you could write it, but some professors want to see every single reagent, so let's write that out. It's going to be in base with heat/over acid. KMnO4 is the short way to put it, but now I just included all the reagents. What that's going to do, guys, is that's going to add a carboxylic acid here. Remember that you always pretty much can oxidize any side chain to a carboxylic acid as long as it has at least one hydrogen on it, which it did. Perfect. The second step would be let's figure out a way to make this an acyl azide. We have to put an N3. The next step would be to use SOCl2. SOCl2 is a very common reagent to turn carboxylic acids into acid chlorides. Now I've just kind of heightened the reactivity of my carboxylic acid derivative. The next two reactions that you're going to find come mostly from your carboxylic acid derivative section of organic chemistry. If you want to brush up on any of these reactions, feel fr
Do you want more practice?
More setsHere’s what students ask on this topic:
What is the Curtius rearrangement and what are its key steps?
The Curtius rearrangement is a synthetic pathway that converts acyl azides into primary amines. The process involves two key steps: first, heating the acyl azide to form an isocyanate intermediate, and second, adding water to the isocyanate, which leads to the formation of carbamic acid. This carbamic acid then undergoes decarboxylation, releasing CO2 and N2 gases, and resulting in the formation of a primary amine. This reaction is particularly useful in organic synthesis for generating amines while eliminating a carbon atom.
What are the reagents required for the Curtius rearrangement?
The Curtius rearrangement requires only two reagents: heat and water. Heat is used in the first step to drive the rearrangement of the acyl azide into an isocyanate intermediate. Water is then added in the second step to react with the isocyanate, leading to the formation of carbamic acid, which subsequently undergoes decarboxylation to produce a primary amine.
What is the role of isocyanate in the Curtius rearrangement?
In the Curtius rearrangement, isocyanate serves as a key intermediate. It is formed in the first step when heat is applied to the acyl azide. The isocyanate then reacts with water in the second step to form carbamic acid. This carbamic acid is unstable and undergoes decarboxylation, releasing CO2 and N2 gases, and ultimately yielding a primary amine. The isocyanate intermediate is crucial for the transformation of the acyl azide into the desired amine product.
What gases are released during the Curtius rearrangement?
During the Curtius rearrangement, two gases are released: carbon dioxide (CO2) and nitrogen (N2). CO2 is released during the decarboxylation of carbamic acid, while N2 is liberated from the decomposition of the acyl azide in the first step. These gas releases are indicative of the reaction's progression and are important for the overall transformation of the acyl azide into a primary amine.
How does the Curtius rearrangement differ from the Hofmann rearrangement?
Both the Curtius and Hofmann rearrangements convert amides into amines with the loss of a carbon atom, but they differ in their starting materials and mechanisms. The Curtius rearrangement starts with an acyl azide and involves the formation of an isocyanate intermediate, whereas the Hofmann rearrangement starts with an amide and involves the formation of an isocyanate via a nitrene intermediate. Additionally, the Curtius rearrangement requires heat and water, while the Hofmann rearrangement typically uses bromine and a strong base like sodium hydroxide.