Chapter 15.12, Problem 27P

(a)

Interpretation Introduction

Interpretation:

The splitting pattern expected in ${}^1\text{H}\text{NMR}$ of the given compounds has to be predicted.

Concept introduction:

The number of signals in the ${}^1\text{H NMR}$ of any compound is equal to the number of protons that are chemically non-equivalent.  Non-equivalent protons are the protons that are present in the different chemical environment.  The equivalent protons produce the same signal which means the set of chemically equivalent protons produces only one signal.

The splitting of signals predicts the number of hydrogens or protons attached to the adjacent carbon in a carbon chain of a compound.  The single signal is split into multiple

peaks called the multiplicity of the signal.  Splitting of signals is done according to the $\left(N+\text{1}\right)$ rule.  $N$ is the number of adjacent non-equivalent protons.

According to the $\left(N+\text{1}\right)$ rule, for a proton-coupled with an $N$ adjacent non-equivalent

protons, the signal split into $\left(N+\text{1}\right)$ peak.  The splitting is mutual.  With this information,

the structure of the compound can be predicted.

(b)

Interpretation Introduction

Interpretation:

The splitting pattern expected in ${}^1\text{H}\text{NMR}$ of the given compounds has to be predicted.

Concept introduction:

The number of signals in the ${}^1\text{H NMR}$ of any compound is equal to the number of protons that are chemically non-equivalent.  Non-equivalent protons are the protons that are present in the different chemical environment.  The equivalent protons produce the same signal which means the set of chemically equivalent protons produces only one signal.

The splitting of signals predicts the number of hydrogens or protons attached to the adjacent carbon in a carbon chain of a compound.  The single signal is split into multiple peaks called the multiplicity of the signal.  Splitting of signals is done according to the $\left(N+\text{1}\right)$ rule. $N$ is the number of adjacent non-equivalent protons.

According to the $\left(N+\text{1}\right)$ rule, for a proton-coupled with an $N$ adjacent non-equivalent protons, the signal split into $\left(N+\text{1}\right)$ peak.  The splitting is mutual.  With this information,

the structure of the compound can be predicted.

(c)

Interpretation Introduction

Interpretation:

The splitting pattern expected in ${}^1\text{H}\text{NMR}$ of the given compounds is to be predicted.

Concept introduction:

The number of signals in the ${}^1\text{H NMR}$ of any compound is equal to the number of protons that are chemically non-equivalent.  Non-equivalent protons are the protons that are present in the different chemical environment.  The equivalent protons produce the same signal which means the set of chemically equivalent protons produces only one signal.

The splitting of signals predicts the number of hydrogens or protons attached to the

adjacent carbon in a carbon chain of a compound.  The single signal is split into multiple

peaks called the multiplicity of the signal.  Splitting of signals is done according to the

$\left(N+\text{1}\right)$ rule.  $N$ is the number of adjacent non-equivalent protons.

According to the $\left(N+\text{1}\right)$ rule, for a proton-coupled with an $N$ adjacent non-equivalent

protons, the signal split into $\left(N+\text{1}\right)$ peak.  The splitting is mutual.  With this information,

the structure of the compound can be predicted.

(d)

Interpretation Introduction

Interpretation:

The splitting pattern expected in ${}^1\text{H}\text{NMR}$ of the given compounds has to be predicted.

Concept introduction:

The number of signals in the ${}^1\text{H NMR}$ of any compound is equal to the number of protons that are chemically non-equivalent.  Non-equivalent protons are the protons that are present in the different chemical environment.  The equivalent protons produce the same signal which means the set of chemically equivalent protons produces only one signal.

The splitting of signals predicts the number of hydrogens or protons attached to theadjacent carbon in a carbon chain of a compound.  The single signal is split into multiple peaks called the multiplicity of the signal.  Splitting of signals is done according to the

$\left(N+\text{1}\right)$ rule.  $N$ is the number of adjacent non-equivalent protons.

According to the $\left(N+\text{1}\right)$ rule, for a proton-coupled with an $N$ adjacent non-equivalent

protons, the signal split into $\left(N+\text{1}\right)$ peak.  The splitting is mutual.  With this information,

the structure of the compound can be predicted.

(e)

Interpretation Introduction

Interpretation:

The splitting pattern expected in ${}^1\text{H}\text{NMR}$ of the given compounds has to be predicted.

Concept introduction:

The number of signals in the ${}^1\text{H NMR}$ of any compound is equal to the number of protons that are chemically non-equivalent.  Non-equivalent protons are the protons that are present in the different chemical environment.  The equivalent protons produce the same signal which means the set of chemically equivalent protons produces only one signal.

The splitting of signals predicts the number of hydrogens or protons attached to the adjacent carbon in a carbon chain of a compound.  The single signal is split into multiple peaks called the multiplicity of the signal.  Splitting of signals is done according to the

$\left(N+\text{1}\right)$ rule.  $N$ is the number of adjacent non-equivalent protons.

According to the $\left(N+\text{1}\right)$ rule, for a proton-coupled with an $N$ adjacent non-equivalent

protons, the signal split into $\left(N+\text{1}\right)$ peak.  The splitting is mutual.  With this information,

the structure of the compound can be predicted.

(f)

Interpretation Introduction

Interpretation:

The splitting pattern expected in ${}^1\text{H}\text{NMR}$ of the given compounds has to be predicted.

Concept introduction:

The number of signals in the ${}^1\text{H NMR}$ of any compound is equal to the number of protons that are chemically non-equivalent.  Non-equivalent protons are the protons that are present in the different chemical environment.  The equivalent protons produce the same signal which means the set of chemically equivalent protons produces only one signal.

The splitting of signals predicts the number of hydrogens or protons attached to the

adjacent carbon in a carbon chain of a compound.  The single signal is split into multiple

peaks called the multiplicity of the signal.  Splitting of signals is done according to the

$\left(N+\text{1}\right)$ rule.  $N$ is the number of adjacent non-equivalent protons.

According to the $\left(N+\text{1}\right)$ rule, for a proton-coupled with an $N$ adjacent non-equivalent

protons, the signal split into $\left(N+\text{1}\right)$ peak.  The splitting is mutual. With this information,

the structure of the compound can be predicted.

(g)

Interpretation Introduction

Interpretation:

The splitting pattern expected in ${}^1\text{H}\text{NMR}$ of the given compounds has to be predicted.

Concept introduction:

The number of signals in the ${}^1\text{H NMR}$ of any compound is equal to the number of protons that are chemically non-equivalent.  Non-equivalent protons are the protons that are present in the different chemical environment.  The equivalent protons produce the same signal which means the set of chemically equivalent protons produces only one signal.

The splitting of signals predicts the number of hydrogens or protons attached to the

adjacent carbon in a carbon chain of a compound.  The single signal is split into multiple

peaks called the multiplicity of the signal.  Splitting of signals is done according to the

$\left(N+\text{1}\right)$ rule.  $N$ is the number of adjacent non-equivalent protons.

According to the $\left(N+\text{1}\right)$ rule, for a proton-coupled with an $N$ adjacent non-equivalent protons, the signal split into $\left(N+\text{1}\right)$ peak.  The splitting is mutual.  With this information,

the structure of the compound can be predicted.

(h)

Interpretation Introduction

Interpretation:

The splitting pattern expected in ${}^1\text{H}\text{NMR}$ of the given compounds has to be predicted.

Concept introduction:

The number of signals in the ${}^1\text{H NMR}$ of any compound is equal to the number of protons that are chemically non-equivalent.  Non-equivalent protons are the protons that are present in the different chemical environment.  The equivalent protons produce the same signal which means the set of chemically equivalent protons produces only one signal.

The splitting of signals predicts the number of hydrogens or protons attached to the

adjacent carbon in a carbon chain of a compound.  The single signal is split into multiple

peaks called the multiplicity of the signal.  Splitting of signals is done according to the

$\left(N+\text{1}\right)$ rule.  $N$ is the number of adjacent non-equivalent protons.

According to the $\left(N+\text{1}\right)$ rule, for a proton-coupled with an $N$ adjacent non-equivalent

protons, the signal split into $\left(N+\text{1}\right)$ peak.  The splitting is mutual.  With this information,

the structure of the compound can be predicted.

(i)

Interpretation Introduction

Interpretation:

The splitting pattern expected in ${}^1\text{H}\text{NMR}$ of the given compounds has to be predicted.

Concept introduction:

The number of signals in the ${}^1\text{H NMR}$ of any compound is equal to the number of protons that are chemically non-equivalent.  Non-equivalent protons are the protons that are present in the different chemical environment.  The equivalent protons produce the same signal which means the set of chemically equivalent protons produces only one signal.

The splitting of signals predicts the number of hydrogens or protons attached to the adjacent carbon in a carbon chain of a compound.  The single signal is split into multiple peaks called the multiplicity of the signal.  Splitting of signals is done according to the

$\left(N+\text{1}\right)$ rule.  $N$ is the number of adjacent non-equivalent protons.

According to the $\left(N+\text{1}\right)$ rule, for a proton-coupled with an $N$ adjacent non-equivalent

protons, the signal split into $\left(N+\text{1}\right)$ peak.  The splitting is mutual.  With this information,

the structure of the compound can be predicted.

(j)

Interpretation Introduction

Interpretation:

The splitting pattern expected in ${}^1\text{H}\text{NMR}$ of the given compounds has to be predicted.

Concept introduction:

The number of signals in the ${}^1\text{H NMR}$ of any compound is equal to the number of protons that are chemically non-equivalent.  Non-equivalent protons are the protons that are present in the different chemical environment.  The equivalent protons produce the same signal which means the set of chemically equivalent protons produces only one signal.

The splitting of signals predicts the number of hydrogens or protons attached to the adjacent carbon in a carbon chain of a compound.  The single signal is split into multiple

peaks called the multiplicity of the signal.  Splitting of signals is done according to the

$\left(N+\text{1}\right)$ rule.  $N$ is the number of adjacent non-equivalent protons.

According to the $\left(N+\text{1}\right)$ rule, for a proton-coupled with an $N$ adjacent non-equivalent

protons, the signal split into $\left(N+\text{1}\right)$ peak.  The splitting is mutual.  With this information,

the structure of the compound can be predicted.

(k)

Interpretation Introduction

Interpretation:

The splitting pattern expected in ${}^1\text{H}\text{NMR}$ of the given compounds has to be predicted.

Concept introduction:

The number of signals in the ${}^1\text{H NMR}$ of any compound is equal to the number of protons that are chemically non-equivalent.  Non-equivalent protons are the protons that are present in the different chemical environment.  The equivalent protons produce the same signal which means the set of chemically equivalent protons produces only one signal.

The splitting of signals predicts the number of hydrogens or protons attached to the adjacent carbon in a carbon chain of a compound.  The single signal is split into multiple peaks called the multiplicity of the signal.  Splitting of signals is done according to the $\left(N+\text{1}\right)$ rule.  $N$ is the number of adjacent non-equivalent protons.

According to the $\left(N+\text{1}\right)$ rule, for a proton-coupled with an $N$ adjacent non-equivalent

protons, the signal split into $\left(N+\text{1}\right)$ peak.  The splitting is mutual.  With this information,

the structure of the compound can be predicted.

(l)

Interpretation Introduction

Interpretation:

The splitting pattern expected in ${}^1\text{H}\text{NMR}$ of the given compounds has to be predicted.

Concept introduction:

The number of signals in the ${}^1\text{H NMR}$ of any compound is equal to the number of protons that are chemically non-equivalent.  Non-equivalent protons are the protons that are present in the different chemical environment.  The equivalent protons produce the same signal which means the set of chemically equivalent protons produces only one signal.

The splitting of signals predicts the number of hydrogens or protons attached to the adjacent carbon in a carbon chain of a compound.  The single signal is split into multiple peaks called the multiplicity of the signal.  Splitting of signals is done according to the $\left(N+\text{1}\right)$ rule. $N$ is the number of adjacent non-equivalent protons.

According to the $\left(N+\text{1}\right)$ rule, for a proton-coupled with an $N$ adjacent non-equivalent protons, the signal split into $\left(N+\text{1}\right)$ peak.  The splitting is mutual. With this information,

the structure of the compound can be predicted.

(m)

Interpretation Introduction

Interpretation:

The splitting pattern expected in ${}^1\text{H}\text{NMR}$ of the given compounds has to be predicted.

Concept introduction:

The number of signals in the ${}^1\text{H NMR}$ of any compound is equal to the number of protons that are chemically non-equivalent.  Non-equivalent protons are the protons that are present in the different chemical environment.  The equivalent protons produce the same signal which means the set of chemically equivalent protons produces only one signal.

The splitting of signals predicts the number of hydrogens or protons attached to the adjacent carbon in a carbon chain of a compound.  The single signal is split into multiple

peaks called the multiplicity of the signal.  Splitting of signals is done according to the

$\left(N+\text{1}\right)$ rule.  $N$ is the number of adjacent non-equivalent protons.

According to the $\left(N+\text{1}\right)$ rule, for a proton-coupled with an $N$ adjacent non-equivalent protons, the signal split into $\left(N+\text{1}\right)$ peak.  The splitting is mutual. With this information,

the structure of the compound can be predicted.