Textbook Question
Tell precisely how you would use the proton NMR spectra to distinguish between the following pairs of compounds.
(a) 1-bromopropane and 2-bromopropane
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Ch. 13 - Nuclear Magnetic Resonance Spectroscopy
Wade9th EditionOrganic ChemistryISBN: 9780135213728
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Table of contents
- Ch.1 - Structure and Bonding107
- Ch. 2 - Acids and Bases; Functional Groups115
- Ch.3 - Structure and Stereochemistry of Alkanes100
- Ch.4 - The Study of Chemical Reactions99
- Ch.5 - Stereochemistry93
- Ch.6 - Alkyl Halides; Nucleophilic Substitution118
- Ch. 7 - Structure and Synthesis of Alkenes; Elimination158
- Ch.8 - Reactions of Alkenes171
- Ch.9 - Alkynes91
- Ch.10 - Structure and Synthesis of Alcohols143
- Ch.11 - Reactions of Alcohols104
- Ch. 12 - Infrared Spectroscopy and Mass Spectrometry22
- Ch. 13 - Nuclear Magnetic Resonance Spectroscopy45
- Ch. 14 - Ethers, Epoxides, and Thioethers72
- Ch. 15 - Conjugated Systems, Orbital Symmetry, and Ultraviolet Spectroscopy89
- Ch. 16 - Aromatic Compounds74
- Ch. 17 - Reactions of Aromatic Compounds126
- Ch. 18 - Ketones and Aldehydes193
- Ch. 19 - Amines129
- Ch. 20 - Carboxylic Acids77
- Ch. 21 - Carboxylic Acid Derivatives141
- Ch. 22 - Condensations and Alpha Substitutions of Carbonyl Compounds175
- Ch. 23 - Carbohydrates and Nucleic Acids93
- Ch. 24 - Amino Acids, Peptides, and Proteins54
Chapter 13, Problem 37
Using a 60-MHz spectrometer, a chemist observes the following absorption: doublet, J = 7 Hz, at δ4.00
(a) What would the chemical shift (δ) be in the 300-MHz spectrum?
(b) What would the splitting value J be in the 300-MHz spectrum?
(c) How many hertz from the TMS peak is this absorption in the 60-MHz spectrum? In the 300-MHz spectrum?
Verified step by step guidance1
Step 1: Understand the relationship between chemical shift (δ) and the spectrometer frequency. The chemical shift (δ) is a dimensionless value expressed in parts per million (ppm) and is independent of the spectrometer frequency. Therefore, the δ value remains the same regardless of the spectrometer frequency.
Step 2: Recognize that the coupling constant (J) is measured in hertz (Hz) and is independent of the spectrometer frequency. This means the J value will remain the same regardless of whether the spectrometer is 60 MHz or 300 MHz.
Step 3: Calculate the distance in hertz from the TMS peak for the 60-MHz spectrum. Use the formula: distance (Hz) = δ (ppm) × spectrometer frequency (MHz). For the 60-MHz spectrum, substitute δ = 4.00 ppm and spectrometer frequency = 60 MHz into the formula.
Step 4: Calculate the distance in hertz from the TMS peak for the 300-MHz spectrum. Use the same formula: distance (Hz) = δ (ppm) × spectrometer frequency (MHz). For the 300-MHz spectrum, substitute δ = 4.00 ppm and spectrometer frequency = 300 MHz into the formula.
Step 5: Summarize the results. The chemical shift (δ) remains the same at 4.00 ppm for both spectrometers. The coupling constant (J) remains the same at 7 Hz for both spectrometers. The distance in hertz from the TMS peak will differ between the 60-MHz and 300-MHz spectrometers, as calculated in steps 3 and 4.
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Key Concepts
Here are the essential concepts you must grasp in order to answer the question correctly.
Chemical Shift
Chemical shift (δ) refers to the resonant frequency of a nucleus relative to a standard reference, typically tetramethylsilane (TMS) in NMR spectroscopy. It is measured in parts per million (ppm) and provides insight into the electronic environment surrounding the nuclei. The chemical shift can change with the frequency of the spectrometer, but the relative position remains constant, allowing for comparisons across different instruments.
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J-Coupling (Spin-Spin Splitting)
J-coupling, or spin-spin splitting, occurs when nuclei interact with each other through chemical bonds, leading to the splitting of NMR signals into multiple peaks. The coupling constant (J) quantifies the interaction strength and is measured in hertz (Hz). This value remains constant regardless of the spectrometer frequency, allowing for consistent interpretation of splitting patterns across different NMR instruments.
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Spectrometer Frequency
The frequency of an NMR spectrometer, measured in megahertz (MHz), affects the sensitivity and resolution of the spectra obtained. While the chemical shift values (δ) are independent of the spectrometer frequency, the absolute frequency of the resonance peaks will change. Understanding how to convert between different spectrometer frequencies is essential for accurate analysis and comparison of NMR data.
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Related Practice
Textbook Question
The following proton NMR spectrum is of a compound of molecular formula C3H8O.
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(a) Propose a structure for this compound.
(b) Assign peaks to show which protons give rise to which signals in the spectrum.
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Textbook Question
Predict the approximate chemical shifts of the protons in the following compounds.
(c) CH3–O–CH2CH2CH2Cl
(d) CH3CH2–C≡C–H
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Textbook Question
Sketch your predictions of the proton NMR spectra of the following compounds.
(b)
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Textbook Question
Predict the multiplicity (the number of peaks as a result of splitting) and the chemical shift for each shaded proton in the following compounds.
(a)
(b)
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Textbook Question
Sketch your predictions of the proton NMR spectra of the following compounds.
(a) CH3–O–CH2CH3
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