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Alkanes
Now let's take a look at how these generalities I've been talking about correspond to
the spectra of some real compounds.
Hexane
| First, let's consider hexane (in spectrum #1 in your workbook). Where does
it have absorptions? |
![Hexane IR spectrum.[61irsp01.JPG (10672 bytes)]](images/61irsp01.JPG)
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| There are three absorptions close to the right of
3000. That corresponds to hydrogen attached to a carbon atom which has only
single bonds. The fact that there are three absorptions does not mean that there
are three hydrogen atoms. Instead, it corresponds to three ways that the hydrogen in the
compound can absorb energy. The rest of the absorptions are in the fingerprint region that
we won't worry about. Altogether, what does this spectrum show? It indicated that hexane
contains carbon and hydrogen and single bonds. In short, hexane is an alkane. |
Octane
| Next, the spectrum for octane (spectrum #2 in your workbook). |
![Octane IR spectrum.[61irsp02.JPG (10352 bytes)]](images/61irsp02.JPG)
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| As with hexane the C-H bonds show up to the right of
3000 and nothing shows up in the multiple bond region. Again, this compound is an
alkane. Notice that there is not much in the spectra that would allow us
to distinguish between hexane and octane. That is characteristic of IR spectra, they will
help identify the class of compound, but not the specific compound. You would have to use
something like the molecular weight to do that. |
Cyclohexane
| Next, cyclohexane (spectrum #3 in your workbook). Again, it is an alkane
as indicated by the location of the absorptions. |
![Cyclohexane IR spectrum.[61irsp03.JPG (10351 bytes)]](images/61irsp03.JPG)
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| There is a difference in fingerprint region, however, and
also there are only two peaks to the right of 3000 rather than three. A
skilled interpreter of these spectra would pick up on that and figure out that this is a
cyclic compound. (That is because the third peak comes from vibrations caused by having
three hydrogen atoms on the carbon atom at the end of the molecule. The absence of the
third peak indicates the absence of three hydrogen atoms at the end of the molecule. In
this case the molecule does not have an end.) |
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E-mail instructor:
Eden Francis
Clackamas Community College
©2001, 2003 Clackamas Community College, Hal Bender
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