What is the Difference Between Pure and Hybrid Orbitals?
🆚 Go to Comparative Table 🆚The key difference between pure and hybrid orbitals lies in their formation and the number of atomic orbitals involved. Here are the main differences:
- Formation: Pure orbitals are the original atomic orbitals that contain electrons of the atom, whereas hybrid orbitals form from the mixing of two or more atomic orbitals.
- Hybridization: Pure orbitals are not hybridized, while hybrid orbitals form via orbital hybridization.
- Nomenclature: Pure orbitals are named as s, p, d, and f orbitals, while hybrid orbitals are named as sp, sp², sp³, etc.
- Stability: Hybridized orbitals are generally more stable than pure orbitals because they allow for better overlap between atomic orbitals, leading to stronger chemical bonds.
- Spatial Arrangement: The spatial arrangement of hybrid orbitals can vary depending on the combination of atomic orbitals involved. For example, sp³ hybrid orbitals point at the vertices of a tetrahedron, oriented at 109.5° from each other.
In summary, pure orbitals are the original atomic orbitals that do not undergo hybridization, while hybrid orbitals are the result of mixing two or more atomic orbitals. Hybrid orbitals are more stable than pure orbitals due to better overlap, and their spatial arrangement depends on the combination of atomic orbitals involved.
Comparative Table: Pure vs Hybrid Orbitals
Here is a table comparing pure and hybrid orbitals:
| Feature | Pure Orbitals | Hybrid Orbitals |
|---|---|---|
| Definition | Pure orbitals are atomic orbitals that contain electrons of the atom. | Hybrid orbitals are molecular orbitals that form from the mixing of atomic orbitals. |
| Nomenclature | Named as s, p, d, and f orbitals. | Named as sp, sp², sp³, etc., depending on the hybridization. |
| Formation | Do not involve the combination of atomic orbitals. | Formed by combining two or more atomic orbitals, resulting in new, equivalent orbitals oriented in specific ways. |
| Spatial Arrangement | s orbitals are spherical, p orbitals are directional (x, y, z axes). | sp hybrids are linear, sp² hybrids are trigonal planar, sp³ hybrids are tetrahedral. |
| Bonding | Pure orbitals are used for bonding in some cases, but their energy levels are not always suitable for chemical bonding. | Hybrid orbitals are more suitable for bonding, as their energy levels are adjusted to optimize electron-electron repulsion and stabilize the molecule. |
In summary, pure orbitals are atomic orbitals that do not mix, while hybrid orbitals are formed by combining atomic orbitals to create new, equivalent orbitals with specific spatial arrangements. Hybrid orbitals are often used in bonding due to their optimized energy levels and ability to minimize electron repulsion.
- Hybridized vs Unhybridized Orbitals
- Atomic Orbital vs Hybrid Orbital
- Hybrid vs Degenerate Orbitals
- Molecular Orbital Theory vs Hybridization Theory
- Molecular Orbital vs Atomic Orbital
- Bonding vs Antibonding Molecular Orbitals
- Sigma vs Pi Molecular Orbitals
- Orbit vs Orbital
- Px Py vs Pz Orbitals
- Spin vs Orbital Angular Momentum
- Molecular Orbital Theory vs Valence Bond Theory
- 1s vs 2s Orbital
- Molecular Geometry vs Electron Geometry
- Orbital Diagram vs Electron Configuration
- sp3d2 vs d2sp3 Hybridization
- Canonical Structure vs Resonance Hybrid
- Atomic Radius vs Ionic Radius
- Escape Velocity vs Orbital Velocity
- Ionic vs Covalent Bonds