# Chapter 4 Solutions

### In-chapter exercises

E4.1:

Using  λν = c, we first rearrange to ν= c/λ  to solve for frequency.

For light with a wavelength of 400 nm, the frequency is 7.50 x 1014 Hz:

In the same way, we calculate that light with a wavelength of 700 nm has a frequency of 4.29 x 1014 Hz.

To calculate corresponding energies:

Using hc/λ, we find for light at 400 nm:

Using the same equation, we find that light at 700 nm corresponds to 40.9 kcal/mol.

E4.2:

A wavenumber of 3000 cm-1 means that 3000 waves fit in one cm (0.01m):

We want to find the length of 1 wave, so we divide numerator and denominator by 3000:

So 3000 cm-1 is equivalent to a wavelength of 3.33 mm.

E4.3:

The ππ* transition in 4-methyl-3-penten-2-one is at 236 nm, which corresponds to 121 kcal/mol:

E4.4:

Molecule A has a longer system of conjugated pi bonds, and thus will absorb at a longer wavelength.  Notice that there is an sp3-hybridized carbon in molecule B which isolates two of the pi bonds from the other three.

E4.5:

We use the formula:

recall from your high school algebra that if y = log(x), then x = 10y , so:

. . . so the intensity of light entering the sample (I0) is 10 times the intensity of the light (at a particular wavelength) that emerges from the sample and is detected (I).  Because %T is simply the reciprocal of this ratio multiplied by 100, we find that A = 1.0 corresponds to 10% transmission.

E4.6: Using ε = A/c, we plug in our values for ε and A and find that c = 3.27 x 10-5M, or 32.7 mM.

E4.7:

Using ε = A/c and plugging in the given values for ε and A, we find that c = 16.3 ng/mL.  However, this is the concentration of the diluted solution - the original solution was 20 times higher (50 mL were removed and diluted to 1000 mL to take the UV measurement).  Thus the concentration of the original solution is (20)(16.3) = 326 ng/mL.

E4.8:

The sample is propanal.  The peak at m/z = 58 is the molecular ion (parent peak), and the peak at m/z = 29 is the formyl acylium ion.  The M+1 peak at m/z = 59 is a molecular ion in which one of the three carbons is a 13C.

### End-of-chapter problems

P4.1:

Without doing any calculation, we can answer the first part of the calculation: electromagnetic waves at 3400 cm-1 are shorter than those at 1690 cm-1 (more waves fit into one centimeter) and thus correspond to a higher frequency.

3400 cm-1  = 2.94 mm = 1.02 x 1014 Hz

1690 cm-1 = 5.92 mm = 5.07 x 1013 Hz

P4.2:

1720 cm-1 corresponds to a wavelength of .01/1720 = 5.81 x 10-6 m, and an energy of 4.92 kcal/mol.

P4.3:

The triple bond in compound I is symmetric, and therefore is not IR-active, so there would be no absorbance in the carbon-carbon triple bond range (2100-2250 cm-1).  In compound II the presence of the fluorines makes the triple bond asymmetric and IR-active, thus the alkyne peak will be observed.  In compound III, we should see not only the carbon-carbon triple bond peak but also an absorbance at approximately 3300 cm-1 due to stretching of the terminal alkyne carbon-hydrogen bond.

P4.4:

All three spectra will have a strong carbonyl stretching peak, but the ester (compound C) carbonyl peak will be observed at a shorter wavelength compared to the ketone (compound B) and the carboxylic acid (compound A).   In addition, Compound A will show a broad absorbance centered at approximately 3000 cm-1 due to carboxylic acid O-H stretching, whereas in the spectrum of compound B we should see the broad absorbance centered at approximately 3300 cm-1 from stretching of the alcohol O-H bond. Compound C will have no broad O-H stretching absorbance.

P4.5:

All three compounds contain alkene functional groups. However, in compound Y the alkene is symmetric and thus we would not expect to see an absorbance from C=C stretching in the 1620-1680 cm-1range.  We would expect to see this peak in the spectra of compounds X and Z; in addition we would expect to see, in the compound X spectrum, a peak in the 3020 - 3080 cm-1 range due to stretching of the terminal alkene C-H bonds.

P4.6:

P4.7:

The change in A340 is DA = 0.220.  Using the expression ε = A/c, we can calculate that this represents a change in the NADH concentration of 3.50 x 10-5 M.  This is in a 1 mL solution, so 3.50 x 10-8 mol have been used up over the course of five minutes, or 7.00 x 10-9 mol (7.00 nmol) per minute on average.

P4.8:

Both starting compounds contain systems of conjugated pi bonds which absorb in the UV range.  The condensation reaction brings these two conjugated systems together to create a single, longer conjugated pi system, which absorbs in the blue part of the visible spectrum.

P4.9:

P4.10:

The molecular ion and the fragments from all three of the typical ketone fragmentation patterns would all have m/z = 98.

P4.11:

Both molecules contain alkene and ketone functional groups, however the degree of pi bond conjugation is different.  Therefore, UV would be the more useful technique to distinguish the two.

P4.12:

Both molecules are straight-chain alkanes with a single ketone group, so their IR spectra are expected to be very similar and neither will absorb strongly in the UV range.   However, the different positions of the ketone (at the C4 vs C5 position) will result in the formation of fragments of different masses in an MS experiment.

Viewing 2 of 2 comments: view all
E.4.4

I believe molecule A has a longer system of conjugated pi bonds with no sp3 hybridization. So, I would suspect molecule A to have more narrow band gaps of pi to pi* versus molecule B with an isolated Pi bond.
Posted 23:14, 9 Dec 2015
Thanks for pointing out that typo! It has been fixed.
Posted 08:38, 10 Dec 2015
Viewing 2 of 2 comments: view all
08:37, 10 Dec 2015

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This material is based upon work supported by the National Science Foundation under Grant Numbers 1246120, 1525057, and 1413739.