1. Hybridization of Orbitals�Sections 9.1 and 9.5 March 14, 2007
2. Tetrahedral Experimentally we know the bond angles (109.5).
But our current understanding of orbitals doesnt allow us to achieve these bond angles.
3. sp3 Hybridization Molecules that have tetrahedral geometry like CH4, NH3, H2O, SO42-, and ClO3- exhibit sp3 hybridization on the central atom.
4. Methane with Hybridized Orbitals Overlap of the Hydrogen 1s orbitals with the hybridized sp3 orbitals from the central Carbon.
5. Trigonal Planar sp2 Hybridization Molecules with trigonal planar geometry like SO3, C2H4, SeS2, CO32-, exhibit sp2 hybridization on the central atom.
6. Hybridized and Unhybridized Orbital View
8. Bonding and hybridized orbitals Hybridized orbitals make sigma bonds
Unhybridized orbitals make pi bonds
http://www.dlt.ncssm.edu/TIGER/chem7.htm
9. Linear geometry - sp Hybridization Molecules that have a linear geometry like CO2, N2O, BeH2, HCN, C2H2 all exhibit sp hybrization on the central atom.
10. CO2 Structure
11. sp Hybridization
12. Pi bonds and Sigma Bonds CO2 exhibits sp hybridization on the C and sp2 hybridization on the Oxygens.
13. N2 Hybridization Diatomic Nitrogen has a Lewis structure showing a triple bond.
14. Hybridized Orbitals When Exceeding the Octet Rule
15. PCl5 dsp3 Hybridized Trigonal bipyramid geometry
SeF4, PCl5, BrF3, XeCl2
16. Octahedral Geometry d2sp3 hybridization
XeF4, BrCl5, SeI6
17. Delocalization of Electrons (9.5) In molecules that show resonance structures, we have a delocalization of electrons.
The available unhybridized p orbitals all overlap and stabilize the structure through the p interactions.
NO3-
