NVAEasyJEE 2025VSEPR Theory & Shapes of Molecules

JEE Chemistry 2025 Question with Solution

The number of molecules/ions that show linear geometry among the following is _____.

SO2\mathrm{SO_2}, BeCl2\mathrm{BeCl_2}, CO2\mathrm{CO_2}, N3\mathrm{N_3^-}, NO2\mathrm{NO_2}, F2O\mathrm{F_2O}, XeF2\mathrm{XeF_2}, NO2+\mathrm{NO_2^+}, I3\mathrm{I_3^-}, O3\mathrm{O_3}

Answer

Correct answer:6

Step-by-step solution

Standard Method

Given: The species are SO2\mathrm{SO_2}, BeCl2\mathrm{BeCl_2}, CO2\mathrm{CO_2}, N3\mathrm{N_3^-}, NO2\mathrm{NO_2}, F2O\mathrm{F_2O}, XeF2\mathrm{XeF_2}, NO2+\mathrm{NO_2^+}, I3\mathrm{I_3^-}, and O3\mathrm{O_3}.

Find: The number of molecules/ions that have linear geometry.

Using VSEPR theory, analyze each species:

  • SO2\mathrm{SO_2}: Bent geometry due to one lone pair on the sulfur atom.
  • BeCl2\mathrm{BeCl_2}: Linear geometry. Beryllium has no lone pairs and is bonded to two chlorine atoms.
  • CO2\mathrm{CO_2}: Linear geometry. Carbon has no lone pairs and is double bonded to each oxygen atom.
  • N3\mathrm{N_3^-}: Linear geometry as the resonance structures contribute to a linear arrangement.
  • NO2\mathrm{NO_2}: Bent geometry due to the presence of a lone electron.
  • F2O\mathrm{F_2O}: Bent geometry due to two lone pairs on the oxygen atom.
  • XeF2\mathrm{XeF_2}: Linear geometry, due to three lone pairs on xenon that arrange themselves to minimize repulsion.
  • NO2+\mathrm{NO_2^+}: Linear geometry. Nitronium ion has no lone pairs on nitrogen.
  • I3\mathrm{I_3^-}: Linear geometry, with iodine atoms bonded symmetrically around a central iodine atom, compensated by three lone pairs.
  • O3\mathrm{O_3}: Bent geometry due to a lone pair on the central oxygen atom.

Therefore, the linear species are BeCl2\mathrm{BeCl_2}, CO2\mathrm{CO_2}, N3\mathrm{N_3^-}, XeF2\mathrm{XeF_2}, NO2+\mathrm{NO_2^+}, and I3\mathrm{I_3^-}.

So, the total number of linear molecules/ions is 66.

Geometry Classification

Given: A list of ten molecules/ions is provided.

Find: How many among them are linear.

The key idea is that linear geometry commonly arises for spsp-hybridized central atoms or for trigonal bipyramidal electron geometry where three lone pairs occupy equatorial positions, as in XeF2\mathrm{XeF_2} and I3\mathrm{I_3^-}.

Classify the species one by one:

  1. SO2\mathrm{SO_2} → bent
  2. BeCl2\mathrm{BeCl_2} → linear
  3. CO2\mathrm{CO_2} → linear
  4. N3\mathrm{N_3^-} → linear
  5. NO2\mathrm{NO_2} → bent
  6. F2O\mathrm{F_2O} → bent
  7. XeF2\mathrm{XeF_2} → linear
  8. NO2+\mathrm{NO_2^+} → linear
  9. I3\mathrm{I_3^-} → linear
  10. O3\mathrm{O_3} → bent

Count the linear ones:

66

Hence, the required numerical answer is 66.

Common mistakes

  • Students often confuse electron pair geometry with molecular geometry. For example, XeF2\mathrm{XeF_2} has five electron domains, but its molecular geometry is linear because only bonded atoms determine shape. Use molecular geometry, not just electron-domain arrangement.

  • A common mistake is treating species like SO2\mathrm{SO_2}, NO2\mathrm{NO_2}, and O3\mathrm{O_3} as linear because they contain multiple bonds or resonance. Resonance does not force linearity. Check the central atom for lone pairs or unpaired electrons before deciding the shape.

  • Students may forget that polyatomic ions such as N3\mathrm{N_3^-}, NO2+\mathrm{NO_2^+}, and I3\mathrm{I_3^-} must also be analyzed by VSEPR. Do not exclude ions from the count; determine their geometry in the same way as neutral molecules.

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