5 Must Know Facts For Your Next Test

1. In an octahedral geometry, bond angles between the surrounding atoms are 90 degrees and 180 degrees, providing a highly symmetrical shape.
2. Common examples of octahedral molecules include SF6 (sulfur hexafluoride) and [Ni(CO)6]2- (nickel carbonyl complex).
3. The octahedral shape is typically formed by central atoms with a coordination number of six, which is often seen in transition metal complexes.
4. The presence of lone pairs on the central atom can distort the ideal octahedral geometry, resulting in variations such as square planar or distorted octahedral shapes.
5. The octahedral arrangement is crucial for understanding complex formation in coordination chemistry and plays a vital role in determining electronic and optical properties.

Review Questions

• How does VSEPR theory explain the formation of octahedral molecular geometry?
  • VSEPR theory explains octahedral molecular geometry by stating that electron pairs surrounding a central atom will arrange themselves to minimize repulsion. With six bonding pairs, these pairs occupy positions at the vertices of an octahedron. This arrangement allows for maximum distance between the pairs, which minimizes repulsive forces and stabilizes the molecule, leading to a 90-degree bond angle characteristic of octahedral shapes.
• Compare and contrast octahedral geometry with trigonal bipyramidal geometry in terms of bond angles and spatial arrangements.
  • Octahedral geometry features bond angles of 90 degrees between adjacent atoms, with a symmetrical arrangement around a central atom. In contrast, trigonal bipyramidal geometry has bond angles of 120 degrees in the equatorial plane and 90 degrees between axial and equatorial positions. While both shapes minimize electron pair repulsion, they differ in their number of surrounding atoms and spatial configurations, with octahedral being suitable for coordination numbers of six.
• Evaluate how hybridization influences the formation of octahedral molecular shapes and their properties.
  • Hybridization plays a critical role in forming octahedral shapes by combining atomic orbitals to create six equivalent hybrid orbitals, known as sp³d² hybridization. This process allows for equal distribution of bonding electrons among the surrounding atoms, creating a stable octahedral structure. The hybridization also affects the molecule's properties, such as its reactivity and interaction with light, as seen in transition metal complexes where d-orbitals participate in bonding.

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