Reactions of pi bonds Flashcards
FOR THIS COURSE, double bonds will act as…
Nucleophiles – reacts by electrophilic addition to them
ie. electron-rich double bonds only
note that double bonds CAN be electrophilic / electron poor due to adjacent C=O withdrawing e- density
main types of electrophilic addition reactions considered in this course
addition of H-X
bromination / iodination
Epoxidation
Hydroboration
reagents for hydrogenation
H2
Pd/C (palladium on inert charcoal support)
note: because H’s are added from the same face (on the metal catalyst) the cis-product often dominates
how to determine major product for addition of H-X to asymmetrical alkene
addition product has most stable carbocation intermediate (ie. rich get richer, and aromatic ring will stabilise significantly)
note: mech should be draw with arrow going from double bond THROUGH the C where the bond will be forming to the electrophile H
product of bromination of alkene
a 1,2, dibrominated alkane product
describe the two-step mechanism for bromination/iodination and the HOMO-LUMO interactions for each
- creating bromonium or iodinium ion
HOMO: C=C 𝜋-bond, LUMO: empty X-X σ*
pi-bond attacks one X, lone pair on that X attacks at C –> bromonium bridge - remaining X- ion attacks at C in Sn2 mech, forming 1,2-dihalogenated product
HOMO: e- in Nucleophilic halide anion
LUMO: C-X σ*
stereochemical outcome of bromination on a ring system
gives rise to trans product due to back face attack at bromonium bridge
reaction conditions for halohydrin formation
bromination IN WATER
(vs bromination in an inert solvent will result in dibrominated product)
mechanism for halohydrin formation
same first step to form bromonium bridge
water acts as the Nu and attacks the bromonium ion instead in the second step
H+ removed by another H2O molecule
Two ways to form epoxides
- by reacting a trans-halohydrin with a base
- epoxidation: from alkene and the peroxy-acid m-CPBA
steps for formation of epoxide from trans-halohydrin
- alcohol is deprotonated by addition of base (eg. NaH)
- Sn2 of attached O- onto C, expelling X- as a leaving group (works very well in trans configuration)
functional group of peroxy-acids
acidic -OOH group
as in like a carboxylic acid group w extra O attached between C and -OH
epoxidation mechanism
and HUMO-LUMO interaction
HOMO: e-rich C=C 𝜋-bond
LUMO: O-O σ* bond (parallels the X-X σ* for bromination)
LOTS of arrows for the mech so practice drawing it!!
but the first arrow goes from the 𝜋-bond through one C to the O closest to the H
stereochemical outcome of epoxidation
depends on the configuration of the starting alkene
both new C-O bonds are formed on the same face of the alkene’s pi-bond, so cis alkene –> cis epoxide and trans–>trans
main purpose of hydroboration
a process used to achieve opposite regioselectivity for addition to an alkene substrate
(ie. opposite to typical ‘Markovnikov selectivity’)
