(a)
Interpretation:
To identify whether the molecule has molecular dipole moment and the direction of the molecular dipole moment.
Concept introduction:
Dipole moment is the electric dipole that is present in the molecule.
Dipole moment in a molecule depends upon the bonds present in it.
The compound may be with a neutral charge but then too it can possess net molecular dipole moment as the push and pull of bonds doesn’t get cancelled completely.
The electronegativity of the connected atoms in a bond determines in which direction the expected dipole moment will be.
The dipole moment will be directed towards the high electronegative atom in the bond.
To identify: The direction of the molecular dipole moment
(b)
Interpretation:
To identify whether the molecule has molecular dipole moment and the direction of the molecular dipole moment.
Concept introduction:
Dipole moment is the electric dipole that is present in the molecule.
Dipole moment in a molecule depends upon the bonds present in it.
The compound may be with a neutral charge but then too it can possess net molecular dipole moment as the push and pull of bonds doesn’t get cancelled completely.
The electronegativity of the connected atoms in a bond determines in which direction the expected dipole moment will be.
The dipole moment will be directed towards the high electronegative atom in the bond.
To identify: The direction of the molecular dipole moment
(c)
Interpretation:
To identify whether the molecule has molecular dipole moment and the direction of the molecular dipole moment.
Concept introduction:
Dipole moment is the electric dipole that is present in the molecule.
Dipole moment in a molecule depends upon the bonds present in it.
The compound may be with a neutral charge but then too it can possess net molecular dipole moment as the push and pull of bonds doesn’t get cancelled completely.
The electronegativity of the connected atoms in a bond determines in which direction the expected dipole moment will be.
The dipole moment will be directed towards the high electronegative atom in the bond.
To identify: The direction of the molecular dipole moment
(d)
Interpretation:
To identify whether the molecule has molecular dipole moment and the direction of the molecular dipole moment.
Concept introduction:
Dipole moment is the electric dipole that is present in the molecule.
Dipole moment in a molecule depends upon the bonds present in it.
The compound may be with a neutral charge but then too it can possess net molecular dipole moment as the push and pull of bonds doesn’t get cancelled completely.
The electronegativity of the connected atoms in a bond determines in which direction the expected dipole moment will be.
The dipole moment will be directed towards the high electronegative atom in the bond.
To identify: The direction of the molecular dipole moment
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Chapter 1 Solutions
ORGANIC CHEMISTRY-NEXTGEN+BOX (2 SEM.)
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