Chapter 9: Molecular Geometry and Bonding Theories

VSEPR Theory (Valence Shell Electron Pair Repulsion)

The VSEPR Theory explains the three-dimensional shapes of molecules by considering the repulsion between electron groups around a central atom. Electron groups arrange themselves to minimize repulsion and maximize their distance from each other.

• Electron Groups include single bonds, double bonds, triple bonds, and lone pairs.

• Multiple bonds (double/triple) count as one electron group in VSEPR.

Electron Geometry vs. Molecular Geometry:

Additional info: For more complex geometries, consult a full molecular geometry chart.

Molecular Shapes (Small Molecules: ≤ 7 Atoms)

To determine the shape of a molecule, follow these steps:

1. Draw the Lewis structure.

2. Count the electron groups around the central atom.

3. Determine the electron domain geometry.

4. Determine the molecular geometry (shape).

Common Shapes and Bond Angles:

• Linear: 180°

• Trigonal planar: 120°

• Tetrahedral: 109.5°

• Trigonal pyramidal: ~107°

• Bent: ~104.5°

• Trigonal bipyramidal: 90°, 120°

• Octahedral: 90°

Example Molecules: CO2, BF3, CH4, NH3, H2O, SO2, PCl5, SF6

Molecular Shape and Polarity

The polarity of a molecule depends on both the polarity of its bonds and its overall geometry.

• Bond Polarity: Determined by the difference in electronegativity () between atoms.

• Small → nonpolar covalent

• Moderate → polar covalent

• Large → ionic character

• Molecular Polarity: A molecule is polar if it contains polar bonds and the dipoles do not cancel due to its geometry.

• Symmetry Rule: If identical atoms surround the central atom symmetrically, the molecule is usually nonpolar.

Examples:

Additional info: Review symmetric/asymmetric geometries for predicting polarity.

Valence Bond Theory (Orbital Overlap)

Valence Bond Theory describes covalent bond formation as the overlap of atomic orbitals. The strength of a bond depends on the amount of overlap and the distance between nuclei.

• Types of Overlap: s–s, s–p, p–p

Example: The H–H bond in H2 forms from s–s overlap.

Hybrid Orbitals

Hybridization explains the observed molecular geometry by combining atomic orbitals into new hybrid orbitals.

• Count electron groups around the central atom to determine hybridization.

Examples:

• CH4, NH3, H2O: 4 groups → sp3

• CO2: 2 groups → sp

• BF3: 3 groups → sp2

Multiple Bonds and Resonance

Sigma (σ) and Pi (π) Bonds:

• Single bond: 1 σ

• Double bond: 1 σ + 1 π

• Triple bond: 1 σ + 2 π

• σ bonds: head-to-head overlap

• π bonds: side-to-side overlap

Resonance: Occurs when multiple valid Lewis structures exist for a molecule, differing only in electron placement. The true structure is a resonance hybrid.

• Resonance equalizes bond lengths, delocalizes charge, and increases stability.

Examples: O3, NO3-, SO2

Chapter 10: Basic Properties of Gases

Properties of Gases

Gases are characterized by their ability to fill containers, high compressibility, low density, and uniform mixing.

• No fixed shape or volume; assume the volume of their container.

• Highly compressible and expandable.

• Low density compared to solids and liquids.

• Mix uniformly with other gases.

Pressure

Pressure is defined as the force exerted per unit area.

• Formula:

• Common units: atm, mmHg (Torr), kPa, Pa

Atmospheric Pressure:

• Standard atmospheric pressure: 1 atm = 760 mmHg = 760 Torr = 101.325 kPa = 101,325 Pa

Pressure Conversions: Use dimensional analysis to convert between units.

• Example: Convert 0.85 atm to mmHg:

Key Skills to Practice

• Drawing accurate Lewis structures

• Determining molecular shape from VSEPR

• Predicting polarity from shape

• Identifying hybridization

• Counting σ and π bonds

• Recognizing resonance structures

• Performing pressure unit conversions