The correct order of bond dissociation energy among $N_2, O_2, O_2^-$ is shown in which of the following arrangements ?
- $N_{2}> O_{2}^{-}>O_{2}$
- $O^{-}_{2}> O_{2}>N_{2}$
- $N_{2}> O_{2}>O_{2}^{-}$
- $O_{2}> O_{2}^{-}>N_{2}$
The Correct Option is C
Solution and Explanation
$N_{2} =Nb=10, Na=4$
$B.O.=\left(N_{2}\right)=\frac{10-4}{2}=3$
$O_{2}=Nb=10, Na=6$
$B.O_{\left(o_2\right)}=\frac{10-6}{2}=2$
$O_{2}^{-}=Nb=10, Na=7$
$B.O._{\left(o_2\right)}=\frac{10-7}{2}=\frac{3}{2}=1.5$
Hence the order of B.O.
$N_{2}>\, O_{2} >\, O_{2}^{-}$
Top JEE Main Chemistry Questions
- The number of isoelectronic species among S2−, C4−, Mn2+, Co3+ and Fe3+ is ‘n’.
If ‘n’ moles of AgCl is formed during the reaction of the complex with formula
CoCl2(en)2NH3
with excess AgNO3 solution, then the number of electrons present in the t2g orbital of the complex is ________.- JEE Main - 2026
- Chemistry
- Organic Chemistry
Write the correct order of rate of reaction of following with PhN$_2$Cl
- JEE Main - 2026
- Chemistry
- Organic Reactions
- K$_{sp}$ of Ag$_2$CrO$_4$ = 32x
K$_{sp}$ of AgBr = 4y Then, the ratio of molarity (solubility) of (1) to (2) is:
- JEE Main - 2026
- Chemistry
- Ionic Equilibrium In Solution
- For first order reaction, rate constant at 27°C and t°C is $1.5 \times 10^3$ and $4.5 \times 10^3$ respectively. If the activation energy of the reaction is 60 kJ, then find the temperature $t$.
- JEE Main - 2026
- Chemistry
- Chemical Kinetics
- C5H10 \(\xrightarrow{h\nu}\) possible structural isomers?
Top JEE Main Molecular Orbital Theory Questions
- Among the species O$_2^+$, N$_2^-$, N$_2^{2-}$ and O$_2^-$ which have same bond order as well as paramagnetic in nature.
- JEE Main - 2026
- Chemistry
- Molecular Orbital Theory
- Pair of species among the following having same bond order as well as paramagnetic character will be:
- JEE Main - 2026
- Chemistry
- Molecular Orbital Theory
- Which of the following is the ratio of 5\(^\text{th}\) Bohr orbit \( (r_5) \) of He\(^+\) & Li\(^{2+}\)?
- JEE Main - 2025
- Chemistry
- Molecular Orbital Theory
- In the following, the number of paramagnetic molecules are: O\(_2\), N\(_2\), F\(_2\), B\(_2\), Cl\(_2\).
- JEE Main - 2025
- Chemistry
- Molecular Orbital Theory
Which of the following statement is true with respect to H\(_2\)O, NH\(_3\) and CH\(_4\)?
(A) The central atoms of all the molecules are sp\(^3\) hybridized.
(B) The H–O–H, H–N–H and H–C–H angles in the above molecules are 104.5°, 107.5° and 109.5° respectively.
(C) The increasing order of dipole moment is CH\(_4\)<NH\(_3\)<H\(_2\)O.
(D) Both H\(_2\)O and NH\(_3\) are Lewis acids and CH\(_4\) is a Lewis base.
(E) A solution of NH\(_3\) in H\(_2\)O is basic. In this solution NH\(_3\) and H\(_2\)O act as Lowry-Bronsted acid and base respectively.
- JEE Main - 2025
- Chemistry
- Molecular Orbital Theory
Top JEE Main Questions
- Let \( f \) be a polynomial function such that \[ f(x^2+1)=x^4+5x^2+2,\quad \text{for all } x\in\mathbb{R}. \] Then \[ \int_0^3 f(x)\,dx \] is equal to:
- JEE Main - 2026
- Functions
- The number of isoelectronic species among S2−, C4−, Mn2+, Co3+ and Fe3+ is ‘n’.
If ‘n’ moles of AgCl is formed during the reaction of the complex with formula
CoCl2(en)2NH3
with excess AgNO3 solution, then the number of electrons present in the t2g orbital of the complex is ________.- JEE Main - 2026
- Organic Chemistry
Write the correct order of rate of reaction of following with PhN$_2$Cl
- JEE Main - 2026
- Organic Reactions
Consider two arrangements of wires. Find the ratio of magnetic field at the centre of the semi–circular part.
- JEE Main - 2026
- Moving charges and magnetism
- K$_{sp}$ of Ag$_2$CrO$_4$ = 32x
K$_{sp}$ of AgBr = 4y Then, the ratio of molarity (solubility) of (1) to (2) is:
- JEE Main - 2026
- Ionic Equilibrium In Solution
Concepts Used:
Molecular Orbital Theory
The Molecular Orbital Theory is a more sophisticated model of chemical bonding where new molecular orbitals are generated using a mathematical process called Linear Combination of Atomic Orbitals (LCAO).
Molecular Orbital theory is a chemical bonding theory that states that individual atoms combine together to form molecular orbitals. Due to this arrangement in MOT Theory, electrons associated with different nuclei can be found in different atomic orbitals. In molecular orbital theory, the electrons present in a molecule are not assigned to individual chemical bonds between the atoms. Rather, they are treated as moving under the influence of the atomic nuclei in the entire molecule.
