Chapter 2, Problem 2G.8E

Interpretation Introduction

Interpretation:

Whether molecules of period 2 are paramagnetic like oxygen molecule or not have to be determined.

Concept Introduction:

Molecular orbital diagram is a linear combination of atomic orbitals of similar energy and similar symmetry. It is formed by the proper overlap of the atomic orbitals.

There are 3 types of molecular orbitals as follows:

1. Bonding molecular orbital: They are formed by the constructive interference of atomic orbitals and electrons in it stabilize the molecule and are of lesser in energy.

2. Antibonding molecular orbital: This type of orbitals increases the energy of molecule and destabilizes it and weakens the bond between the atoms.

3. Non-bonding molecular orbital: These types of orbitals have energy similar to atomic orbitals that is addition or removal of electron does not change the energy of molecule.

The order of energy in molecular orbital follows two rules as follows:

1. For atomic number less than or equal to 14 order of energy is,

  ${\sigma }_{1\text{s}}<{\sigma }_{1\text{s}}^{\ast }<{\sigma }_{\text{2s}}<{\sigma }_{\text{2s}}^{\ast }<\left({\text{π}}_{2{\text{p}}_{\text{x}}}={\text{π}}_{2{\text{p}}_{\text{y}}}\right)<{\sigma }_{{\text{2p}}_{\text{z}}}<\left({\text{π}}_{2{\text{p}}_{\text{x}}}^{\ast }={\text{π}}_{2{\text{p}}_{\text{y}}}^{\ast }\right)<{\sigma }_{{}_{{\text{2p}}_{\text{z}}}}^{\ast }$

2. For atomic number more than 14 order of energy is,

  ${\sigma }_{1\text{s}}<{\sigma }_{1\text{s}}^{\ast }<{\sigma }_{\text{2s}}<{\sigma }_{\text{2s}}^{\ast }<{\sigma }_{{\text{2p}}_{\text{z}}}<\left({\text{π}}_{2{\text{p}}_{\text{x}}}={\text{π}}_{2{\text{p}}_{\text{y}}}\right)<\left({\text{π}}_{2{\text{p}}_{\text{x}}}^{\ast }={\text{π}}_{2{\text{p}}_{\text{y}}}^{\ast }\right)<{\sigma }_{{}_{{\text{2p}}_{\text{z}}}}^{\ast }$

Bond order $\left(b\right)$ is defined as total number of bonds between the atoms. It is calculated as follows:

  $b=\frac{1}{2}\left[\begin{array}{l}\text{number of elctrons in bonding orbitals}-\\ \text{number of electrons in antibonding orbitals}\end{array}\right]$        (1)