
Amines can be made by the reduction of nitriles, which in turn can be made from...
Amines can be made by the reduction of nitriles, which in turn
can be made from an alkyl halide. Draw the structures of a starting
alkyl bromide and the intermediate nitrile that would be used in
the synthesis of 3-methylbutylamine (also known as isoamylamine).
Do not show free ions.
"Carboxylic acids can be made by the hydrolysis of nitriles,
which in turn can be made from an alkyl halide. Draw the structures
of a starting alkyl bromide and the intermediate nitrile that would
be used in the synthesis of 3-methylbutanoic acid (also known as
isovaleric acid). Do not show free ions."
I answered the first part right but it is saying that the
second part is incorrect. On my carbon that is triple bonded to the
nitrogen has a...
Carboxylic acids can be made by the hydrolysis of nitriles, which in turn can be made from an alkyl halide. Draw the structures of a starting alkyl bromide and the intermediate nitrile that would be used in the synthesis of 3-methylbutanoic acid (also known as isovaleric acid). Do not show free ions.
Carboxylic acids can be made by the hydrolysis of nitriles, which
in turn can be made from an alkyl halide. Draw the structures of a
starting alkyl bromide and the intermediate nitrile that would be
used in the synthesis of 3-methylbutanoic acid (isovaleric acid) Do
not show free ions.
alkyl bromide nitrile isovaleric
acid
Unsymmetrical ethers can be made by the Williamson synthesis, in
which an alkoxide ion reacts with an alkyl bromide. Draw the
structure of the alkoxide and the alkyl bromide needed to produce
2-ethoxy-2-methylpropane (a.k.a t-butyl ethyl ether), shown below.
Show charges where appropriate.
Unsymmetrical ethers can be made by the Williamson synthesis, in which an alkoxide ion reacts with an alkyl bromide. Draw the structure of the alkoxide and the alkyl bromide needed to produce 2-ethoxy-2-methylpropane (a.k.a t-butyl ethyl ether),...
Draw the structure
Unsymmetrical ethers can be made by the Williamson synthesis, in which an alkoxide ion reacts with an alkyl bromide. Draw the structure of the alkoxide and the alkyl bromide needed to produce 2-ethoxy-2-methylpropane (a.k.a t-butyl ethyl ether), shown below. Show charges where appropriate. alkoxide alkyl bromide ether Br
Unsymmetrical ethers can be made by the Williamson synthesis, in which an alkoxide ion reacts with an alkyl bromide. Draw the structure of the alkoxide and the alkyl bromide needed to produce 2-ethoxy-2-methylpropane (a.k.a t-butyl ethyl ether), shown below. Show charges where appropriate. alkoxide alkyl bromide ether + Br
Unsymmetrical ethers can be made by the Williamson synthesis, in
which an alkoxide ion reacts with an alkyl bromide. Draw the
structure of the alkoxide and the alkyl bromide needed to produce
2-ethoxy-2-methylpropane (a.k.a t-butyl ethyl ether), shown below.
Show charges where appropriate.
Unsymmetrical ethers can be made by the Williamson synthesis, in which an alkoxide ion reacts with an alkyl bromide. Draw the structure of the alkoxide and the alkyl bromide needed to produce 2-ethoxy-2-methylpropane (a.k.a t-butyl ethyl ether), shown below. Show charges where appropriate.
Unsymmetrical ethers can be made by the Williamson synthesis, in
which an alkoxide ion reacts with an alkyl bromide. Draw the
structure of the alkoxide and the alkyl bromide needed to produce
2-ethoxy-2-methylpropane (a.k.a t-butyl ethyl ether), shown below.
Show charges where appropriate.