Section 6.8 Addition of Hydrogen 249
Hydroboration–oxidation of a terminal
alkyne forms an aldehyde.
Herbert H. M. Lindlarwas born in
Switzerland in 1909 and received a
Ph.D. from the University of Bern.
He worked at Hoffmann-La Roche
and Co. in Basel, Switzerland, and he
authored many patents. His last
patent was a procedure for isolating
the carbohydrate xylose from the
waste produced in paper mills.
is noton the terminal carbon), whereas hydroboration–oxidation of a terminal alkyne
produces an aldehyde(the carbonyl group ison the terminal carbon).
PROBLEM 13
Give the products of (1) mercuric-ion-catalyzed addition of water and (2) hydroboration–
oxidation for the following:
a. 1-butyne b. 2-butyne c. 2-pentyne
PROBLEM 14
There is only one alkyne that forms an aldehyde when it undergoes either acid- or
mercuric-ion-catalyzed addition of water. Identify the alkyne.
6.8 Addition of Hydrogen
Hydrogen adds to an alkyne in the presence of a metal catalyst such as palladium, plat-
inum, or nickel in the same manner that it adds to an alkene (Section 4.11). It is diffi-
cult to stop the reaction at the alkene stage because hydrogen readily adds to alkenes
in the presence of these efficient metal catalysts. The product of the hydrogenation re-
action, therefore, is an alkane.
The reaction can be stopped at the alkene stage if a “poisoned”(partially deactivat-
ed) metal catalyst is used. The most commonly used partially deactivated metal cata-
lyst is Lindlar catalyst, which is prepared by precipitating palladium on calcium
carbonate and treating it with lead(II) acetate and quinoline. This treatment modifies
the surface of the palladium, making it much more effective at catalyzing the addition
of hydrogen to a triple bond than to a double bond.
Because the alkyne sits on the surface of the metal catalyst and the hydrogens are
delivered to the triple bond from the surface of the catalyst, only syn addition of hy-
drogen occurs (Section 5.19). Syn addition of hydrogen to an internal alkyne forms a
cis alkene.
Internal alkynes can be converted into trans alkenesusing sodium (or lithium) in
liquid ammonia. The reaction stops at the alkene stage because sodium (or lithium) re-
acts more rapidly with triple bonds than with double bonds. Ammonia (bp=- 33 °C)
CH 3 CH 2 C H 2
2-pentyne
CCH 3 + catalyst
Lindlar
HH
cis-2-pentene
CH 3 CH 2 CH 3
CC
H 2
CH 3 CH 2 CCHPt/C CH 3 CH 2 CH
H 2
CH (^2) Pt/C CH 3 CH 2 CH 2 CH 3
alkyne alkene alkane
a ketone
an aldehyde
H 2 O, H 2 SO 4
HgSO 4
CH 3 CCH
CH 3 CCH 2 CH 3 CCH 3
OH O
- disiamylborane
2. HO−, H 2 O 2 , H 2 O CH^3 CH CH
CH 3 CH 2 CH
OH O
(CH 3 COO−) 2 Pb2+
lead(II) acetate
quinoline
N
Tutorial:
Hydrogenation/Lindlar
catalyst
BRUI06-238_262r4 24-03-2003 11:47 AM Page 249