Now we're going to talk about a specific reaction called a Hofmann elimination. The name Hofmann elimination can be a little confusing because we've used both of these terms before. We've talked plenty about elimination reactions in Organic Chemistry 1 and we learned that they could either follow Zaitsev's rule or Hofmann's rule. But when I mention Hofmann elimination here, I'm not referring to that. I'm referring to a specific reaction called Hofmann elimination, not Hofmann's rule regarding elimination. This is also referred to as exhaustive methylation or Hofmann degradation. If you hear any of those words or if your professors call it any of those other terms, just know that this is the same reaction. The name Hofmann elimination actually is helpful for us because it's going to serve to remind us that we're going to produce a Hofmann elimination product, meaning that it is going to follow Hofmann's rule but specifically it's going to be within an amine. In Organic Chemistry 1, we learned that alcohols can be eliminated, dehydrated to form double bonds. That was actually a reaction called dehydration. In the same way, amines can too. But they need to be turned into a good leaving group because amines as they are, if you were to kick off an NH2-, it's a terrible leaving group. That's like the strongest base ever. The point of the first step of this reaction is going to be to try to make the nitrogen a good leaving group, so then we can kick it out and do an elimination reaction with a base. That's exactly what the first step is. The first step is going to be some kind of alkyl halide, usually an alkyl iodide. You may see it written as in excess or you may not. In the absence of data telling you excess or a number of equivalents, always assume that there's excess. In this case, I don't have to write excess but your professor may be nice and write excess. Now what that's going to do is it's g
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Hofmann Elimination - Online Tutor, Practice Problems & Exam Prep
The Hofmann elimination, also known as exhaustive methylation or Hofmann degradation, transforms amines into alkenes by first converting the amine into a quaternary ammonium salt using excess alkyl halide. This salt then undergoes elimination with a base, typically silver oxide, yielding the least substituted alkene, known as the Hofmann product. The reaction favors the less substituted product due to steric hindrance from the bulky nitrogen leaving group, which affects the required anti-coplanar geometry for elimination. Understanding this mechanism is crucial for mastering elimination reactions in organic chemistry.
General Reaction
Video transcript
Mechanism
Provide the Major Product
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More setsHere’s what students ask on this topic:
What is Hofmann elimination and how does it differ from Hofmann's rule?
Hofmann elimination, also known as exhaustive methylation or Hofmann degradation, is a reaction that transforms amines into alkenes. It involves converting the amine into a quaternary ammonium salt using excess alkyl halide, followed by elimination with a base like silver oxide, yielding the least substituted alkene (Hofmann product). This differs from Hofmann's rule, which is a guideline for predicting the major product in elimination reactions, stating that the least substituted alkene is favored. Hofmann elimination specifically refers to the reaction mechanism involving amines, while Hofmann's rule applies more broadly to elimination reactions.
What are the reagents used in Hofmann elimination?
The reagents used in Hofmann elimination include an excess of alkyl halide (usually alkyl iodide) and silver oxide (Ag2O). The alkyl halide is used to convert the amine into a quaternary ammonium salt, making it a good leaving group. Silver oxide then acts as the base to facilitate the elimination reaction, resulting in the formation of the least substituted alkene.
Why does Hofmann elimination favor the least substituted alkene?
Hofmann elimination favors the least substituted alkene due to steric hindrance from the bulky nitrogen leaving group. For an E2 elimination reaction to occur, the anti-coplanar geometry is required. The bulky quaternary ammonium group makes it energetically more favorable for the elimination to occur at the less substituted carbon, avoiding steric clashes. This results in the formation of the Hofmann product, which is the least substituted alkene.
What is the role of silver oxide in Hofmann elimination?
In Hofmann elimination, silver oxide (Ag2O) serves as the base that facilitates the elimination reaction. When combined with iodine ions (I-), silver oxide forms silver iodide (AgI) and hydroxide ions (OH-). The hydroxide ions then act as the base to deprotonate the β-hydrogen, leading to the formation of the double bond and the elimination of the quaternary ammonium group, resulting in the least substituted alkene.
Can you explain the mechanism of Hofmann elimination?
The mechanism of Hofmann elimination involves several steps: First, the amine reacts with an excess of alkyl halide (e.g., CH3I) to form a quaternary ammonium salt through exhaustive methylation. This quaternary ammonium salt is a good leaving group. Next, silver oxide (Ag2O) reacts with iodine ions (I-) to produce hydroxide ions (OH-). The hydroxide ions then deprotonate a β-hydrogen, leading to the formation of a double bond and the elimination of the quaternary ammonium group, resulting in the least substituted alkene.
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