According to molecular orbital theory, which of the following statements is(are) correct?

O_{2}^{2 +}

is expected to have a longer bond length than

O_{2}

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N_{2}^{+}

and

N_{2}^{-}

have the same bond order

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H e_{2}^{+}

has the same energy as two isolated

H e

atoms

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C_{2}^{2 -}

is expeced to be diamagnetic

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Solution

The correct option is D $C_{2}^{2 -}$ is expeced to be diamagnetic
For $C_{2}^{2 -}$
Number of electrons $= 14$
Molecular orbital electronic configuration; $σ 1 s^{2} σ^{} 1 s^{2} σ 2 s^{2} σ^{} 2 s^{2} π 2 p_{y}^{2} = π 2 p_{z}^{2} σ 2 p_{x}^{2}$
Number of bonding electrons = 10
Number of antibonding electrons = 4
Hence, Bond order = 3
Magnetic character = Diamagnetic

For $O_{2}^{2 +}$
Number of electrons $= 14$
Molecular orbital electronic configuration; $σ 1 s^{2} σ^{} 1 s^{2} σ 2 s^{2} σ^{} 2 s^{2} π 2 p_{y}^{2} = π 2 p_{z}^{2} σ 2 p_{x}^{2}$
Number of bonding electrons = 10
Number of antibonding electrons = 4
Hence, Bond order = 3
Magnetic character = Diamagnetic

For $O_{2}$
Number of electrons $= 16$
Molecular orbital electronic configuration; $σ 1 s^{2} σ^{} 1 s^{2} σ 2 s^{2} σ^{} 2 s^{2} σ 2 p_{x}^{2} π 2 p_{y}^{2} = π 2 p_{z}^{2} π^{} 2 p_{y}^{2} = π^{} 2 p_{z}^{2}$
Number of bonding electrons = 10
Number of antibonding electrons = 6
Hence, Bond order = 2
Magnetic character = Paramagnetic

For $N_{2}^{+}$
Number of electrons $= 13$
Molecular orbital electronic configuration; $σ 1 s^{2} σ^{} 1 s^{2} σ 2 s^{2} σ^{} 2 s^{2} π 2 p_{y}^{2} = π 2 p_{z}^{2} σ 2 p_{x}^{1}$
Number of bonding electrons = 9
Number of antibonding electrons = 4
Hence, Bond order = 2.5
Magnetic character = Paramagnetic

For $N_{2}^{-}$
Number of electrons $= 15$
Molecular orbital electronic configuration; $σ 1 s^{2} σ^{} 1 s^{2} σ 2 s^{2} σ^{} 2 s^{2} σ 2 p_{x}^{2} π 2 p_{y}^{2} = π 2 p_{z}^{2} π^{} 2 p_{y}^{2} = π^{} 2 p_{z}^{1}$
Number of bonding electrons = 10
Number of antibonding electrons = 5
Hence, Bond order = 2.5
Magnetic character = Paramagnetic

For $H e_{2}^{+}$
Number of electrons $= 3$
Molecular orbital electronic configuration; $σ 1 s^{2} σ^{*} 1 s^{1}$
Number of bonding electrons = 2
Number of antibonding electrons = 1
Hence, Bond order = 0.5
Magnetic character = Paramagnetic

Thus (a) is correct.
(b) Bond order of $O_{2}^{2 +} > O_{2}$ , thus bond length of $O_{2}^{2 +} < O_{2}$ Thus, incorrect.
(c) $N_{2}^{+}$ and $N_{2}^{-}$ have same bond order.
(d) $H e_{2}^{+}$ with bond order = $0.5$ is more stable thus, less energy than isolated $H e$ atoms. Thus, (d) is incorect.

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