What is the Difference Between Bonding and Antibonding Molecular Orbitals?
🆚 Go to Comparative Table 🆚Bonding and antibonding molecular orbitals are formed when atomic orbitals of two atoms combine to create molecular orbitals. The main differences between these orbitals are:
- Electron density: In bonding orbitals, electrons spend most of their time between the nuclei of the two atoms, leading to an increase in electron density between the nuclei. In antibonding orbitals, electrons spend most of their time outside the nuclei of the two atoms, leading to a decrease in electron density between the nuclei.
- Energy levels: Bonding molecular orbitals are always lower in energy (more stable) than the component atomic orbitals, while antibonding molecular orbitals are always higher in energy (less stable) than the component atomic orbitals.
- Stability: Placing electrons in bonding orbitals stabilizes the molecule, as the electron density between the nuclei increases. Conversely, placing electrons in antibonding orbitals decreases the stability of the molecule, as the electron density between the nuclei decreases.
- Contribution to molecular shape: Bonding molecular orbitals represent the shape of the molecule, while antibonding molecular orbitals do not contribute to the shape of the molecule.
In general, electrons in bonding orbitals pull the nuclei closer together, grouping atoms as a molecule and increasing bond order. On the other hand, electrons in antibonding orbitals pull the nuclei away from each other, decreasing bond order.
Comparative Table: Bonding vs Antibonding Molecular Orbitals
The main difference between bonding and antibonding molecular orbitals lies in their energy levels, electron density, and stabilization of the molecule. Here is a comparison table highlighting the key differences:
Feature | Bonding Orbitals | Antibonding Orbitals |
---|---|---|
Energy Level | Lower energy | Higher energy |
Electron Density | Increasing between the nuclei of two atoms | Decreasing between the nuclei of two atoms |
Stability | Stabilizes the molecule | Destabilizes the molecule |
Filled First | Bonding orbitals are filled first | Antibonding orbitals are filled after bonding orbitals |
Bonding orbitals are formed when electrons spend most of their time between the nuclei of two atoms, resulting in an increase in electron density between the nuclei. This leads to a stabilization of the molecule. On the other hand, antibonding orbitals are formed when electrons spend most of their time outside the nuclei of two atoms, leading to a decrease in electron density between the nuclei and destabilizing the molecule.
- Antibonding vs Nonbonding
- Molecular Orbital vs Atomic Orbital
- Molecular Orbital Theory vs Valence Bond Theory
- Bond Dipole vs Molecular Dipole
- Molecular Orbital Theory vs Hybridization Theory
- Atomic Orbital vs Hybrid Orbital
- Ionic Bonding vs Metallic Bonding
- Hybridized vs Unhybridized Orbitals
- Ionic vs Covalent Bonds
- Coordinate Covalent Bond vs Covalent Bond
- Bond Energy vs Bond Enthalpy
- Electrovalent vs Covalent Bond
- Bond Energy vs Bond Dissociation Energy
- Molecular Geometry vs Electron Geometry
- Covalent vs Noncovalent Bonds
- Polar Bonds vs Polar Molecules
- Hybrid vs Degenerate Orbitals
- Pure vs Hybrid Orbitals
- Double Bond vs Single Bond