The
hydrogenation of alkenes to
alkanes is
exothermic. The amount of energy released during a hydrogenation reaction, known as the heat of hydrogenation, is inversely related to the stability of the starting alkene: the more stable the alkene, the lower its heat of hydrogenation. Examining the heats of hydrogenation for various alkenes reveals that stability increases with the amount of substitution. The increase in stability associated with additional substitutions is the result of several factors.
Alkyl groups are electron donating by inductive effect, and increase the electron density on the sigma bond of the alkene. Also, alkyl groups are sterically large, and are most stable when they are far away from each other. In an alkane, the maximum separation is that of the
tetrahedral bond angle, 109.5°. In an alkene, the bond angle increases to near 120°. As a result, the separation between alkyl groups is greatest in the most substituted alkene.
Hyperconjugation, which describes the stabilizing interaction between the
HOMO of the alkyl group and the
LUMO of the double bond, also helps explain the influence of alkyl substitutions on the stability of alkenes. In regards to
orbital hybridization, a bond between an
sp2 carbon and an
sp3 carbon is stronger than a bond between two sp3-hybridized carbons. Computations reveal a dominant stabilizing hyperconjugation effect of 6 kcal/mol per alkyl group.
Steric effects In
E2 elimination reactions, a base abstracts a proton that is beta to a leaving group, such as a halide. The removal of the proton and the loss of the leaving group occur in a single, concerted step to form a new double bond. When a small, unhindered base – such as
sodium hydroxide,
sodium methoxide, or
sodium ethoxide – is used for an E2 elimination, the Zaytsev product is typically favored over the least substituted alkene, known as the
Hofmann product. For example, treating 2-Bromo-2-methyl butane with sodium ethoxide in ethanol produces the Zaytsev product with moderate selectivity. : Due to
steric interactions, a bulky base – such as
potassium tert-butoxide,
triethylamine, or
2,6-lutidine – cannot readily abstract the proton that would lead to the Zaytsev product. In these situations, a less sterically hindered proton is preferentially abstracted instead. As a result, the Hofmann product is typically favored when using bulky bases. When 2-Bromo-2-methyl butane is treated with potassium
tert-butoxide instead of sodium ethoxide, the Hofmann product is favored. : Steric interactions within the substrate also prevent the formation of the Zaytsev product. These
intramolecular interactions are relevant to the distribution of products in the
Hofmann elimination reaction, which converts
amines to alkenes. In the Hofmann elimination, treatment of a quaternary ammonium iodide salt with
silver oxide produces hydroxide ions, which act as a base and eliminate the tertiary amine to give an alkene. : In the Hofmann elimination, the least substituted alkene is typically favored due to intramolecular steric interactions. The quaternary ammonium group is large, and interactions with alkyl groups on the rest of the molecule are undesirable. As a result, the conformation necessary for the formation of the Zaytsev product is less energetically favorable than the conformation required for the formation of the Hofmann product. As a result, the Hofmann product is formed preferentially. The
Cope elimination is very similar to the Hofmann elimination in principle but occurs under milder conditions. It also favors the formation of the Hofmann product, and for the same reasons.
Stereochemistry In some cases, the stereochemistry of the starting material can prevent the formation of the Zaytsev product. For example, when menthyl chloride is treated with sodium ethoxide, the Hofmann product is formed exclusively, but in very low yield: : This result is due to the stereochemistry of the starting material. E2 eliminations require
anti-periplanar geometry, in which the proton and leaving group lie on opposite sides of the C-C bond, but in the same plane. When menthyl chloride is drawn in the
chair conformation, it is easy to explain the unusual product distribution. : Formation of the Zaytsev product requires elimination at the 2-position, but the
isopropyl group – not the proton – is
anti-periplanar to the chloride leaving group; this makes elimination at the 2-position impossible. In order for the Hofmann product to form, elimination must occur at the 6-position. Because the proton at this position has the correct orientation relative to the leaving group, elimination can and does occur. As a result, this particular reaction produces only the Hofmann product. ==See also==