(a)
Interpretation:
The splitting pattern is to be determined for the type of H highlighted in the given molecule.
Concept introduction:
Each chemically distinct proton generates a signal in proton nmr spectroscopy. The signal may be modified, split into a number of lines, by nearby protons. Typically only protons three bonds away produce distinct splitting of the signal of interest. The number of lines, called multiplicity, into which the signal is split, equals
Answer to Problem 16.58P
The signal for the highlighted H will be a singlet.
Explanation of Solution
The structure of the molecule with the specific H highlighted is
The signal for that H can be split by any protons on adjacent carbons.
There is only one such proton. The proton on the nearest OH group is four bonds away, so it will not have any effect. Only the proton on the left is close enough to have an effect, but it is structurally equivalent to the one of interest. Structurally identical protons do not cause splitting of a signal.
Therefore, the signal of the highlighted proton is not split and appears as a singlet.
The multiplicity of the signal is determined on the basis of the number of structurally distinct protons coupled to it.
(b)
Interpretation:
The splitting pattern is to be determined for the type of H highlighted in the given molecule.
Concept introduction:
Each chemically distinct proton generates a signal in proton nmr spectroscopy. The signal may be modified, split into a number of lines, by nearby protons. Typically only protons three bonds away produce distinct splitting of the signal of interest. The number of lines, called multiplicity, into which the signal is split, equals
The intensities of the individual lines in such signals are in fixed ratios, given by Pascal’s triangle.
Answer to Problem 16.58P
The signal for the highlighted proton will appear to be a multiplet, with nine peaks.
Explanation of Solution
The structure of the molecule with the highlighted proton is
The highlighted proton has a total of eight coupled protons, six from the two methyl groups and two from the methylene bridge.
Although the methyl protons and the methylene protons are structurally not exactly equivalent, their coupling constants are similar. Therefore, instead of the complex splitting expected of two distinctly differernt proton groups, they will cause a splitting that resembles the splitting by eight equivalent protons. Therefore, the signal will be split into a multiplet with nine peaks.
The multiplicity of the signal is determined on the basis of the number of structurally distinct protons coupled to it.
(c)
Interpretation:
The splitting pattern is to be determined for the type of H highlighted in the given molecule.
Concept introduction:
Each chemically distinct proton generates a signal in proton nmr spectroscopy. The signal may be modified, split into a number of lines, by nearby protons. Typically only protons three bonds away produce distinct splitting of the signal of interest. The number of lines, called multiplicity, into which the signal is split, equals
Answer to Problem 16.58P
The signal of the first highlighted protons, from the end methyl group will be split into a triplet. The signal for the second highlighted type will be split into a quartet.
Explanation of Solution
The molecule and the highlighted protons are
The protons coupled to each of these are shown in the drawing below:
The one on the left is coupled to two protons from the methylene group. Therefore, the signal for the first type of protons will be split into a triplet.
The second group is coupled to three protons from the methyl group to its right. Therefore, this signal will be split into a quartet.
The multiplicity of the signal is determined on the basis of the number of structurally distinct protons coupled to it.
(d)
Interpretation:
The splitting pattern is to be determined for the type of H highlighted in the given molecule.
Concept introduction:
Each chemically distinct proton generates a signal in proton nmr spectroscopy. The signal may be modified, split into a number of lines, by nearby protons. Typically only protons three bonds away produce distinct splitting of the signal of interest. The number of lines, called multiplicity, into which the signal is split, equals
Answer to Problem 16.58P
The signal for the given proton is split into a doublet.
Explanation of Solution
The structure of the molecule with the highlighted proton is
Only one proton is coupled to the highlighted one. Both are
Therefore, the signal of the highlighted proton will be split into a doublet.
The multiplicity of the signal is determined on the basis of the number of structurally distinct protons coupled to it.
(e)
Interpretation:
The splitting pattern is to be determined for the type of H highlighted in the given molecule.
Concept introduction:
Each chemically distinct proton generates a signal in proton nmr spectroscopy. The signal may be modified, split into a number of lines, by nearby protons. Typically only protons three bonds away produce distinct splitting of the signal of interest. The number of lines, called multiplicity, into which the signal is split, equals
Answer to Problem 16.58P
The signal of the first highlighted H is a triplet and that of the second is a singlet.
Explanation of Solution
The structure of the molecule with the highlighted protons is
The first of these, in the middle of the chain, has two coupled protons while the second, at the end, has no coupled protons.
Therefore, the signal of the first one will be split into a triplet while that of the second will remain a singlet.
The multiplicity of the signal is determined on the basis of the number of structurally distinct protons coupled to it.
(f)
Interpretation:
The splitting pattern is to be determined for the type of H highlighted in the given molecule.
Concept introduction:
Each chemically distinct proton generates a signal in proton nmr spectroscopy. The signal may be modified, split into a number of lines, by nearby protons. Typically only protons three bonds away produce distinct splitting of the signal of interest. The number of lines, called multiplicity, into which the signal is split, equals
Answer to Problem 16.58P
The splitting pattern for the given H will be a doublet of triplets (or a triplet of doublets).
Explanation of Solution
The structure of the molecule with the highlighted H is
There are two protons present at the indicated position. They appear to be structurally equivalent, but they are actually diastereotopic. Each one of them is coupled to two identical protons (Hc), as shown below:
So signal for each proton (Ha and Hb) is split into a triplet by the two coupled protons (Hc). So effectively, the signal will be a doublet of triplets.
The multiplicity of the signal is determined on the basis of the number of structurally distinct protons coupled to it.
Want to see more full solutions like this?
Chapter 16 Solutions
Organic Chemistry: Principles and Mechanisms (Second Edition)
- Give the structure(s) of the product(s) for the reactions below, and be sure to indicate any relative stereochemistry (you can assume that each of the Diels-Alder reactions will proceed with endo selectivity). Draw out relevant enantiomer(s) if they are expected to form. If no reaction is expected to occur under the indicated conditions, then write "no reaction" or NR, and explain why you would expect nothing to occur. If more than one product is formed, please indicate which one will be the major product or if they will be formed in equal amounts. In all cases, equimolar amounts of both components/reagents are present unless indicated otherwise .arrow_forwardCalculate the residence time of strontium (Sr2+) in the world ocean, given that the average concentration of strontium in the world’s rivers is approximately 0.87 µmol L-1 (5 pts).arrow_forwardA package contains 1.33lbs of ground round. If it contains 29% fat, how many grams of fat are in the ground? arrow_forward
- How is the resonance structure formed to make the following reaction product. Please hand draw the arrows showing how the electrons move to the correct position. Do not use an AI answer. Please draw it yourself or don't bother.arrow_forwardPart II Calculate λ max of the following compounds using wood ward- Fiecer rules a) b) c) d) e) OH OH dissolved in dioxane Br Br dissolved in methanol. NH₂ OCH 3 OHarrow_forward6. Match each of the lettered items in the column on the left with the most appropriate numbered item(s) in the column on the right. Some of the numbered items may be used more than once and some not at all. a. Z = 37 1. b. Mn 2. C. Pr element in period 5 and group 14 element in period 5 and group 15 d. S e. [Rn] 7s¹ f. d block metal 3. highest metallic character of all the elements 4. paramagnetic with 5 unpaired electrons 5. 4f36s2 6. isoelectronic with Ca²+ cation 7. an alkaline metal 8. an f-block elementarrow_forward
- Draw all formal charges on the structures below as is and draw 1 resonance structure that is more stable.arrow_forwardPart II. xiao isolated a compound TAD (Ca H 10 N₂) from tobacco and obtained its IR spectrum. Xiao proposed a chemical structure shown below: % Transmittance 4000 3500 3000 2500 2000 Wavenumber (cm-1) 1500 1000 (a) Explain why her proposed structure is inconsistent with the IR spectrum obtained (b) TAD exists as a tautomer of the structure xiao proposed. Draw the structure and explain why it is more compatible with the obtained spectrum. (C) what is the possible source for the fairly intense signal at 1621cm1arrow_forwardAE>AE₁ (Y/N) AE=AE₁ (Y/N) AEarrow_forwardTreatment of 2-phenylpropan-2-amine with methyl 2,4-dibromobutanoate in the presence of a nonnucleophilic base, R3N, involves two successive SN2 reactions and gives compound A. ? NH2 Br Br Propose a structural formula for compound A. You do not have to explicitly draw H atoms. You do not have to consider stereochemistry. In cases where there is more than one answer, just draw one. R3N C14H19NO2 + 2 R3NH*Br Aarrow_forwardCorrectly name this compound using the IUPAC naming system by sorting the components into the correct order. Br IN Ν Harrow_forwardHow is the radical intermediate for this structure formed? Can you please draw arrows from the first radical to the resonance form that would result in this product? I'm lost.arrow_forwardarrow_back_iosSEE MORE QUESTIONSarrow_forward_ios
ChemistryChemistryISBN:9781305957404Author:Steven S. Zumdahl, Susan A. Zumdahl, Donald J. DeCostePublisher:Cengage Learning
ChemistryChemistryISBN:9781259911156Author:Raymond Chang Dr., Jason Overby ProfessorPublisher:McGraw-Hill Education
Principles of Instrumental AnalysisChemistryISBN:9781305577213Author:Douglas A. Skoog, F. James Holler, Stanley R. CrouchPublisher:Cengage Learning
Organic ChemistryChemistryISBN:9780078021558Author:Janice Gorzynski Smith Dr.Publisher:McGraw-Hill Education
Chemistry: Principles and ReactionsChemistryISBN:9781305079373Author:William L. Masterton, Cecile N. HurleyPublisher:Cengage Learning
Elementary Principles of Chemical Processes, Bind...ChemistryISBN:9781118431221Author:Richard M. Felder, Ronald W. Rousseau, Lisa G. BullardPublisher:WILEY