1. HOMONUCLEAR DIATOMIC MOLECULES: VALENCE BOND (VB) THEORY
VALENCE BOND THEORY
HOMONUCLEAR DIATOMIC MOLECULES: VALENCE BOND (VB) THEORY
Chapter 2
Dr. Shuchita Agrawal
BTIRT Sironja, Sagar

2. In covalent bonding, as two nuclei approach each other their atomic orbitals overlap.
As the amount of overlap increases, the energy of the interaction decreases.
At some distance the minimum energy is reached.

3. The minimum energy corresponds to the bonding distance (or bond length).
As the two atoms get closer, their nuclei begin to repel and the energy increases.
At the bonding distance, the attractive forces between nuclei and electrons just balance the repulsive forces (nucleus-nucleus, electron-electron)

5. A covalent bond forms when the orbitals of two atoms overlap and the overlap region, which is between the nuclei, is occupied by a pair of electrons.
A set of overlapping orbitals has a maximum of two electrons that must have opposite spins.
The greater the orbital overlap, the stronger (more stable) the bond.

6. The valence atomic orbital's in a molecule are different from those in isolated atoms.
There is a hybridization of atomic orbitals to form molecular orbitals.

8. HYBRIDIZATION
The number of hybrid orbitals obtained equals the number of atomic orbitals mixed.
The type of hybrid orbitals obtained varies with the types of atomic orbitals mixed. .

9. sp hybrid orbital The sp hybrid orbitals in gaseous BeCl2
atomic orbitals
hybrid orbitals
The sp hybrid orbitals in gaseous BeCl2

10. orbital box diagrams with orbital contours

11. sp2 hybrid orbitals
When we mix n atomic orbitals we must get n hybrid orbitals.
sp2 hybrid orbitals are formed with one s and two p orbitals, therefore, there is one un hybridized p orbital remaining.
The large lobes of sp2 hybrids lie in a trigonal plane.
All molecules with trigonal planar electron pair geometries have sp2 orbitals on the central atom.

12. The sp2 hybrid orbitals in BF3.

13. sp3 hybrid orbitals
sp3 hybrid orbitals are formed from one s and three p orbitals, therefore, there are four large lobes.
Each lobe points towards the vertex of a tetrahedron.
The angle between the large lobes is 109.5

14. The sp3 hybrid orbitals in CH4.

15. The sp3 hybrid orbitals in NH3.

16. The sp3 hybrid orbitals in H2O.

17. Geometrical arrangements characteristic of hybrid orbital sets
Atomic orbital set
Hybrid orbital set
Geometry
Examples
s, p
Two sp
BeF2, HgCl2
s, p, p
Three sp2
BF3, SO3
s, p, p, p
Four sp3
CH4, NH3, H2O, NH4+

18. Composition and orientation of orbitals

19. MULTIPLE BONDS Have  and -bonds.
In -bonds, the electron density lies on the axis between the nuclei. All single bonds are -bonds.
-Bonds: electron density lies above and below the plane of the nuclei.
A double bond consists of one -bond and one -bond.

20. A triple bond has one -bond and two -bonds.
Often, the p-orbitals involved in -bonding come from un hybridized orbitals.

21. Ethane, C2H6 s-sp3 overlaps to σ bonds both Cs are sp3 hybridized
relatively even distribution of electron density over all σ bonds
sp3-sp3 overlap to form a σ bond

22. Ethylene, C2H4
One - and one -bond with both C atoms being sp2 hybridized.
Both C atoms with trigonal planar electron pair and molecular geometries.

23. overlap in one position - σ
p overlap - π
electron density

24. Acetylene, C2H2 In acetylene:
the electron pair geometry of each C is linear, therefore, the C atoms are sp hybridized.
the sp hybrid orbitals form the C-C and C-H -bonds.
there are two unhybridized p-orbitals.
both un hybridized p-orbitals form the two -bonds, one -bond is above and below the plane of the nuclei and the other -bond is in front and behind the plane of the nuclei.

25. EXAMPLE Describe the types of bonds and orbitals in acetone, (CH3)2CO
SOLUTION
Use the Lewis structures to ascertain the arrangement of groups and shape at each central atom. Postulate the hybrid orbitals taking note of the multiple bonds and their orbital overlaps.
π bonds
σ bonds

26. Delocalized π bonding
So far all the bonds we have encountered are localized between two nuclei.
In the case of benzene:
there are 6 C-C  bonds, 6 C-H  bonds.
each C atom is sp2 hybridized.
there are 6 un hybridized p orbitals on each C atom.

27. In benzene there are two options for the 3  bonds:
localized between C atoms or
delocalized over the entire ring (i.e. the  electrons are shared by all 6 C atoms).
Experimentally, all C-C bonds are the same length in benzene, therefore, all C-C bonds are of the same type (recall single bonds are longer than double bonds).

28. Restricted rotation of π-bonded molecules in C2H2Cl2
cis trans-

29. General conclusions on multiple bonds
Every two atoms share at least 2 electrons.
Two electrons between atoms on the same axis as the nuclei are  bonds.
 bonds are always localized.
If two atoms share more than one pair of electrons, the second and third pair form  bonds.
When resonance structures are possible, delocalization is also possible.

30. Thanks
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