Julia-Lythgoe olefination mechanism

The last step of the Julia-Lythgoe olefination is an elimination, which is typically performed with sodium amalgam and starts with an Elcb elimination to give an alkenyl sulfone (mechanistic analysis Figure 4.40) with its reduction to the alkene following in situ. Both the related mechanism and an explanation of the resulting fraws-selectivity will be outlined later in Figure 17.85. 

Lythgoe, Kocienski and their coworkers investigated the scope, stereochemistry and mechanism of the classical Julia olefination (also called the Juha-Lythgoe olefination) and paved the way for its broad application in target-oriented synthesis [87-90]. The bias towards fi-olefins, with the isomer ratio being typically in the range 7/3 to 9/1 for primary unhindered sulfones and aldehydes, marks a distinctive stereochemical feature of the reaction. 

Julia-Lythgoe olefmation is probably the most important method for synthesizing acceptor-free, -configured alkenes, starting from an aldehyde and a primary alkylphenyl sulfone. In this two-step procedure, first the sulfone reacts with the aldehyde to form an acetyl-protected alcoholate and second this species undergoes Elcb elimination to afford the desired alkene. (Sylvestre) Julia olefination is a one-step procedure. It also affords -configured olefins from an aldehyde and an alkylsulfone as substrates, but is limited to base-resistant aldehydes. The most advanced variant is (Sylvestre) Julia-Kocienski olefination, which is also a one-step procedure and is applicable to all kinds of aldehydes. The mechanism is shown below. 

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