terminal (monosubstituted) alkyne
compounds with triple bond at the end of the carbon chain
alkyne
triple bond between carbons
disubstituted alkynes
carbon carbon triple bonds are internal
most distinctive aspect of acetylene and terminal alkynes
their acidity
-most acidic of all hydrocarbons
dehydration of ethylene
- leads to acetylene and H2 gas
- reaction is endothermic
fatty acids
carboxylic acids with unbranched chains of 12-20 carbon atoms
nomenclature of alkynes
-ane is replaced by -yne
if there is a double bond and a triple bond in compound, which ever bond has the lowest number is named first )ties are broken in favor of the double bond)
physical properties of alkynes
- low density
- low water-solubility
- boiling points similar to alkanes
hybridization of alkynes
sp hybridization with angles of 180 degrees between carbons (linear)
structural features of alkanes, alkenes, alkynes
- geometry changes from tetrahedral->trigonal planar->linear
- the C-C and C-H bonds become shorter and stronger
- the acidity of the C-H increases
- sp3->sp2->sp hybridization states
s character in C-H bonds
sp3 (25%), sp2 (33%), sp (50%)
sp character in acetylene
- electrons are in a sp orbital which means that they are held more tightly to the nucleus
- this means that electrons do not have the freedom to fool around with H+
carbanion
-conjugate base of a hydrocarbon
-ex. HC~CH –> HC~C:
CH4 –> CH3:
acid vs base
- strong acid has a weak conjugate base
- weak acid has a strong conjugate base
lower pKa
stronger acid
acetylene
-a very strong acid in terms of hydrocarbons, therefore it has a weak conjugate base
electronegativity of carbon
-increases with its s character (sp3<sp)
hydrocarbon acidity
-increases with its s character
anions of acetylene and terminal alkynes
-are nuclephilic and react with methyl and primary alkyl halides to form C-C bonds by nucleophilic substitution
carbon-carbon bond forming reactions
-are used to prepare alkynes
alkynation of acetylene
-acetylene is converted to its conjugate base by sodium amide (NaNH2)
HC~CH + NaNH2 –> HC~CNa + NH3
-SN2 an alkyl halide is added, HC~CNa acts as a nucleophile, displacing halide
HC~CNa + CH3CH2Br –> HC~CCH2CH3 + NaBr
alkynation of acetylene
-synthesis is via SN2 but requires either a methyl or or a primary alkyl halide
double dehydrohalongenation
preparation of alkynes by elimination reactions
geminal dihalide
halide in which both halogens are on the same carbon
H X
R-C-C-R
H X
