Q. 13 The bond order in 𝑁2
2− species is
(A) 2
(B) 2.5
(C) 3
(D) 3.5
Introduction
The bond order of N22− is a frequently asked question in competitive exams that test concepts of chemical bonding and molecular orbital theory.
Knowing how to calculate this bond order helps in predicting bond length, bond strength and magnetic behaviour of the N22− species.
Step‑by‑Step Solution for N22−
1. Total electrons in N22−
- Neutral N2 has 14 electrons (7 from each nitrogen atom).
- The 2− charge adds 2 more electrons, so N22− has a total of 16 electrons.
2. Valence MO ordering for nitrogen
For molecules up to nitrogen, the energy order of the 2p molecular orbitals is:
σ(2s), σ*(2s), π(2px) = π(2py), σ(2pz)
3. MO configuration of N22−
- Core (1s and 2s) orbitals:
σ1s2 σ1s*2 σ2s2 σ2s*2
→ 8 electrons (4 bonding, 4 antibonding). - Remaining 8 electrons (in 2p orbitals) are filled as:
π2px2 π2py2 σ2pz2 π*2p2
(two electrons in the π* antibonding orbitals).
4. Bonding and antibonding electrons
- Bonding electrons:
σ1s2, σ2s2, π2px2, π2py2, σ2pz2
→ 10 bonding electrons in total. - Antibonding electrons:
σ1s*2, σ2s*2, π*2p2
→ 6 antibonding electrons in total.
5. Bond order formula and calculation
Bond order is calculated using the formula:
Bond order = (Number of bonding electrons − Number of antibonding electrons) / 2
For N22−:
Bond order = (10 − 6) / 2 = 4 / 2 = 2
Therefore, the bond order in N22− is 2, which matches option (A).
Why the Other Options Are Incorrect
Option (B) 2.5
- Bond order 2.5 is obtained for N2− or N2+, not for N22−.
- In those species, only one electron occupies a 2p antibonding orbital, giving 10 bonding and 5 antibonding electrons, so bond order = (10 − 5) / 2 = 2.5.
- N22− has two electrons in π* antibonding orbitals, so its bond order must be lower, not 2.5.
Option (C) 3
- Neutral N2 has bond order 3 with configuration:
σ1s2 σ1s*2 σ2s2 σ2s*2 π2p4 σ2p2. - Here, bonding = 10 and antibonding = 4, so bond order = (10 − 4) / 2 = 3, with no 2p antibonding electrons.
- Adding two extra electrons to form N22− fills π* antibonding orbitals and reduces the bond order to 2 instead of keeping it at 3.
Option (D) 3.5
- A bond order of 3.5 would require fewer antibonding electrons than neutral N2, which is not possible for N22−.
- N22− has two electrons in π* antibonding orbitals, which significantly lowers bond order, so 3.5 is inconsistent with its MO electron configuration.
Comparison of N2 Species
| Species | Total electrons | Bonding electrons | Antibonding electrons | Bond order | Magnetic nature |
|---|---|---|---|---|---|
| N2 | 14 | 10 | 4 | 3 | Diamagnetic |
| N2− | 15 | 10 | 5 | 2.5 | Paramagnetic |
| N22− | 16 | 10 | 6 | 2 | Diamagnetic |
