We’ve gone through elimination reactions before – treatment of alkyl halides with base gives alkenes.
Some time ago we discussed elimination reactions here. Elimination reactions follow the general pattern below, where two adjacent bonds to carbon are broken – usually C-H and C-X, where X is a leaving group – and in place we form a new π bond.
If we can form alkenes through elimination reactions of alkyl halides, it’s natural to ask: can we also use elimination reactions to form alkynes? Perhaps through a reaction like this one?
The answer is yes! Although to be fair, these types of molecules [alkenyl halides] are perhaps not the most familiar to us so far. We’ve only seen them once, and that was a post about how they can be synthesized from alkynes. For our purposes, in order to synthesize them it’s common practice to start with an alkyl di halide.
In other words, we start with an alkyl di-halide, and then do two elimination reactions – one to form the alkenyl halide, and a second to form the alkyne.
Let’s have a look.
There are two types of alkyl dihalides we’ve met so far. Vicinal dihalides have halogens on adjacent carbons – “in the vicinity”, if you will. Treatment of vicinal dihalides with strong base can lead to an elimination reaction [through the E2 mechanism] giving an alkenyl halide. Treatment of this alkenyl halide with a second equivalent of base then gives the alkyne.
In previous posts we saw that a common base used for elimination reactions are alkoxide bases such as sodium ethoxide. But here, we typically go for a more powerful base, sodium amide [NaNH2].
Here’s an illustration of how it works.
In the first step, NaNH2 is the base in an elimination reaction [E2] to give the alkenyl bromide. In the second reaction, likewise a second equivalent of NaNH2 performs a second elimination reaction to form the alkyne.
This is one example – a rare example, I may add – of an elimination reaction that works on an sp2 hybridized carbon. You might recall me writing at some point that reactions of the SN1/SN2/E1/E2 types typically don’t occur on carbons other than sp3 hybridized systems. This is a rare exception!
Finally, what’s often not mentioned in this reaction is that the product alkyne, if terminal [i.e. has a C-H on the end] is acidic [pKa 25] – any excess NaNH2 will thus remove the alkyne C-H and give the alkynyl anion. So if a terminal alkyne is formed, three equivalents of NaNH2 will be consumed; the alkyne is protonated upon workup, usually by adding water.
Geminal dihalides contain two halogen atoms attached to the same carbon. Treatment of geminal dihalides with NaNH2 likewise gives alkynes through two successive elimination reactions. [We haven’t really covered any reactions that form geminal dihalides, except for the di-addition of HX to alkynes. So if you happened to start off with an alkyne and made a geminal dihalide with it, this would be a way of getting the alkyne back].
In total, the elimination reactions described above represent a second way of making alkynes, other than through SN2 of acetylides with alkyl halides.
Let’s bring it back. Who cares? What does it matter that we can do this?
OK. Let’s start putting some reactions together that show why this might be important.
Let’s say we wanted to make an alkyne. But all we have to start with is an alkene. How might we get there?
- We’ve just learned how to make alkynes from vicinal dihalides.
- How might we make a vicinal dihalide from an alkene?
So we can start off with an alkene… and brominate… and then add two equivalents of strong base to give ourselves the alkyne.
This is a quick example of multi-step organic synthesis. We will soon see much more of this in the context of alkynes!
Next Post: Alkynes Are A Blank Canvas