(a)
Interpretation:
The high-resolution proton NMR spectrum of ethyl nitrite is to be stated.
Concept introduction:
The nuclear magnetic resonance (NMR) instrument analyzes the material’s molecular structure by placing the material in the strong magnetic field and measuring the spins.
The NMR spectroscopy measures the following property of the material molecules.
- Chemical shift:
Appearance of the atomic group composition in the molecule.
- The spin-spin coupling constant:
It provides information about the appearance of the adjacent atoms.
- Relaxation time:
It provides information about molecular dynamics.
- Signal intensity:
It provides the quantitative information about the atomic ratios within a molecule which determines the molecular structure, and proportions of different compounds in a mixture.
(b)
Interpretation:
The high-resolution proton NMR spectrum of acetic acid is to be stated.
Concept introduction:
The nuclear magnetic resonance (NMR) instrument analyzes the material’s molecular structure by placing the material in the strong magnetic field and measuring the spins.
The NMR spectroscopy measures the following property of the material molecules.
- Chemical shift:
Appearance of the atomic group composition in the molecule.
- The spin-spin coupling constant:
It provides information about the appearance of the adjacent atoms.
- Relaxation time:
It provides information about molecular dynamics.
- Signal intensity:
It provides the quantitative information about the atomic ratios within a molecule which determines the molecular structure, and proportions of different compounds in a mixture.
(c)
Interpretation:
The high-resolution proton NMR spectrum of methyl- i- propyl
Concept introduction:
The nuclear magnetic resonance (NMR) instrument analyzes the material’s molecular structure by placing the material in the strong magnetic field and measuring the spins.
The NMR spectroscopy measures the following property of the material molecules.
- Chemical shift:
Appearance of the atomic group composition in the molecule.
- The spin-spin coupling constant:
It provides information about the appearance of the adjacent atoms.
- Relaxation time:
It provides information about molecular dynamics.
- Signal intensity:
It provides the quantitative information about the atomic ratios within a molecule which determine the molecular structure, and proportions of different compounds in a mixture.
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Chapter 19 Solutions
Principles of Instrumental Analysis
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- 1 (c) 2-Methyl-3-pentanol reacts with PCC to form compound F. (i) Draw the structure of F. (ii) In the mass spectrum, identify the m/z value of the molecular ion peak for compound F. (ii) Fragmentation of radical cation F exhibits two fragment ion peaks at m/z 57 and m/z 71. Propose the structures of these two fragments. (iv) Draw the resonance structure for each of the cation in (iii).arrow_forwardPredict the masses and the structures of the most abundant fragments observed in the mass spectra of the following compounds. (a) cyclohexyl isopropyl ether (b) tert-butyl propyl aminearrow_forwardThe 1H NMR spectrum of methylbenzene (C6H5CH3) recorded on a 500 Mhz spectrometer consists of signals at chemical shifts of 2.21 parts per million and 7.10 ppm. calculate the frequency, downfield of TMS, of each absorption.arrow_forward
- The 1H NMR spectrum of chloromethane recorded on a 300 Hz NMR spectrometer consists of signals at 444 Hz and 1071 Hz downfield from TMS. Calculate the chemical shift of each absorption. Give answer in parts per million.arrow_forwardDescribe the 1H-NMR spectrum of 4-bromoaniline (chemical shift, integration, multiple). Make a table and describe the results.arrow_forwardPredict and explain the proton NMR of Butanol and 2-chlorobutane. Identify the most prominent differences.arrow_forward
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