Textbook Question
The base peak in Figure 14.51 has m/z 45. Suggest a molecular formula and a structure for this fragment.
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15. Analytical Techniques:IR, NMR, Mass Spect
Mass Spect:Fragmentation
Back15. Analytical Techniques:IR, NMR, Mass Spect
Mass Spect:Fragmentation
- Multiple Choice
Draw the most likely ion fragment of the molecule
- Multiple Choice
Draw the most likely ion fragment of the molecule
- Multiple Choice
What would be the value of the base peak (m/z)?
- Multiple ChoiceA mass spectrum has an M and M + 2 peak in an ~ 3 : 1 ratio. Which atom is likely present in this molecule?
- Multiple ChoicePinacolone has a base peak in its mass spectrum at m/z 57. What is the structure corresponding to this mass?
- Multiple ChoiceWhich of the following is NOT expected to be a major peak in the mass spectrum for the given molecule?
- Textbook Question
Predict the masses and the structures of the most abundant fragments observed in the mass spectra of the following compounds.
(c) 4-methylpentan-2-ol
- Textbook Question
Predict the masses and the structures of the most abundant fragments observed in the mass spectra of the following compounds.
(b) 3-methylhex-2-ene
- Textbook Question
Predict the masses and the structures of the most abundant fragments observed in the mass spectra of the following compounds. (a) 2-methylpentane
- Textbook Question
Account for the peaks at m/z 87, 111, and 126 in the mass spectrum of 2,6-dimethylheptan-4-ol.
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- Textbook Question
Ethers are not easily differentiated by their infrared spectra, but they tend to form predictable fragments in the mass spectrum. The following compounds give similar but distinctive mass spectra.
Both compounds give prominent peaks at m/z 116, 73, 57, and 43. But one compound gives a distinctive strong peak at 87, and the other compound gives a strong peak at 101. Determine which compound gives the peak at 87 and which one gives the peak at 101. Propose fragmentations to account for the ions at m/z 116, 101, 87, and 73.
- Textbook Question
Show the fragmentations that give rise to the peaks at m/z 43, 57, and 85 in the mass spectrum of 2,4-dimethylpentane (Figure 12-17).
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- Textbook Question
A laboratory student added 1-bromobutane to a flask containing dry ether and magnesium turnings. An exothermic reaction resulted, and the ether boiled vigorously for several minutes. Then she added acetone to the reaction mixture and the ether boiled even more vigorously. She added dilute acid to the mixture and separated the layers. She evaporated the ether layer, and distilled a liquid that boiled at 143 °C. GC–MS analysis of the distillate showed one major product with a few minor impurities. The mass spectrum of the major product is shown here.
(b) Explain why the molecular ion is or is not visible in the mass spectrum, and show what ions are likely to be responsible for the strong peaks at m/z 59 and 101.
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- Textbook Question
Using curved arrows, show the principal fragments you would expect to see in the mass spectrum of each of the following compounds:
b.