Concept explainers
(a)
Interpretation:
The splitting pattern expected in
Concept introduction:
The number of signals in the
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
According to the
protons, the signal split into
the structure of the compound can be predicted.
(b)
Interpretation:
The splitting pattern expected in
Concept introduction:
The number of signals in the
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
According to the
the structure of the compound can be predicted.
(c)
Interpretation:
The splitting pattern expected in
Concept introduction:
The number of signals in the
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
According to the
protons, the signal split into
the structure of the compound can be predicted.
(d)
Interpretation:
The splitting pattern expected in
Concept introduction:
The number of signals in the
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
According to the
protons, the signal split into
the structure of the compound can be predicted.
(e)
Interpretation:
The splitting pattern expected in
Concept introduction:
The number of signals in the
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
According to the
protons, the signal split into
the structure of the compound can be predicted.
(f)
Interpretation:
The splitting pattern expected in
Concept introduction:
The number of signals in the
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
According to the
protons, the signal split into
the structure of the compound can be predicted.
(g)
Interpretation:
The splitting pattern expected in
Concept introduction:
The number of signals in the
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
According to the
the structure of the compound can be predicted.
(h)
Interpretation:
The splitting pattern expected in
Concept introduction:
The number of signals in the
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
According to the
protons, the signal split into
the structure of the compound can be predicted.
(i)
Interpretation:
The splitting pattern expected in
Concept introduction:
The number of signals in the
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
According to the
protons, the signal split into
the structure of the compound can be predicted.
(j)
Interpretation:
The splitting pattern expected in
Concept introduction:
The number of signals in the
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
According to the
protons, the signal split into
the structure of the compound can be predicted.
(k)
Interpretation:
The splitting pattern expected in
Concept introduction:
The number of signals in the
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
According to the
protons, the signal split into
the structure of the compound can be predicted.
(l)
Interpretation:
The splitting pattern expected in
Concept introduction:
The number of signals in the
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
According to the
the structure of the compound can be predicted.
(m)
Interpretation:
The splitting pattern expected in
Concept introduction:
The number of signals in the
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
According to the
the structure of the compound can be predicted.
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