User:Amy515/Β-Hydride elimination

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β-Hydride elimination is a reaction in which an alkyl group bonded to a metal centre is converted into the corresponding metal-bonded hydride and an alkene.^[1] The alkyl must have hydrogens on the β-carbon. For instance butyl groups can undergo this reaction but methyl groups cannot. The metal complex must have an empty (or vacant) site cis to the alkyl group for this reaction to occur. Moreover, for facile cleavage of the C–H bond, a d electron pair is needed for donation into the σ* orbital of the C–H bond. Thus, d⁰ metals alkyls are generally more stable to β-hydride elimination than d² and higher metal alkyls and may form isolable agostic complexes, even if an empty coordination site is available.^[2]

The β-hydride elimination can either be a vital step in a reaction or an unproductive side reaction. The Shell higher olefin process relies on β-hydride elimination to produce α-olefins which are used to produce detergents. Illustrative of a sometimes undesirable β-hydride elimination, β-hydride elimination in Ziegler–Natta polymerization results in polymers of decreased molecular weight.^[3] In the case of nickel- and palladium-catalyzed couplings of aryl halides with alkyl Grignard reagents, the β-hydride elimination can lower the yield. The production of branched polymers from ethylene relies on chain walking, a key step of which is β-hydride elimination. In Hydroformylation, β-hydride elimination can act as a side reaction that influences product regioselectivity.^[4] For example, in the hydroformylation of open chain unsaturated ethers, it reverses the formation of branched metal-alkyl intermediates at high temperatures.^[5] This results in a greater yield of linear products.

In some cases, β-hydride elimination is the first in a series of steps. For instance in the synthesis of RuHCl(CO)(PPh₃)₃ from ruthenium trichloride, triphenylphosphine and 2-methoxyethanol, an intermediate alkoxide complex undergoes a β-hydride elimination to form the hydride ligand and the pi-bonded aldehyde which then is later converted into the carbonyl (carbon monoxide) ligand.

β-hydride elimination occurs commonly for metal-alkyl complexes. The process transforms a metal-bound alkyl group into an alkene with the release of a metal hydride. Notably, β-hydride elimination can also occur for other ligands, such as alkoxides, via similar mechanisms.

The transformation can be divided into the following stages:

1) Alignment of the beta hydrogen

The initial step begins with the coordination of the substrate, typically an alkyl or aryl complex, to the metal center. This coordination aligns the reacting alkyl group near the hydride, enabling subsequent reactions.^[6] The geometric arrangement of the alkyl relative to the metal, along with the presence of vacant sites on the metal, determines the feasibility of the elimination process.^[7]

2) Hydride Transfer

After the coordination step, the elimination process proceeds with the transfer of a hydride (H-) from the metal to the β-carbon of the alkyl group. This step is often facilitated by the availability of d-electrons on the metal, which can overlap with the σ* orbital of the C–H bond on the β-carbon.^[7] The hydride transfer initiates the breaking of the C–H bond while simultaneously forming a new C=C double bond, leading to the generation of an alkene. This creates a departing metal hydride species.

3) Formation of Alkene

As the hydride transfers, a π-bond is formed between the α and β carbons, resulting in the generation of an alkene. The stability and substituent effects at the β-position greatly influence the ease of this bond-migration process. The geometry of the alkaline product is significant as it dictates further reactions and the mechanism's overall outcome.

4) Regeneration of the Catalyst

After the formation of the alkene, the released metal hydride, can either re-enter the catalytic cycle to react with another substrate or be further modified through subsequent reactions. This regeneration allows the metal complex to continue facilitating additional reactions without being consumed.

5) Energy Considerations and Transition States

Each of these steps is associated with specific activation energy and transition states. The transition states often involve a configuration where the metal center is coordinated to both the alkyl group and the departing hydride, bringing into play a delicate balance between sterics and electronics. Understanding these energy landscapes, including the height of activation barriers and stability of intermediates, is crucial for optimizing conditions and improving reaction yields.