Atomic Orbital Hybridization Lewis structure
Valence Bond Theory
Valence Bond Theory
Application: Can be used to explain the bonding of molecules
Limitation: Doesn't describe geometry 11. 3 –the Hybridization of molecules
Atom must go from ground state"Basic" to excited state by absorbing energy and "Basic" promoting an electron Valence Bond Theory Bond T The number of hybrid orbitals equals the total number of atomic orbitals thatValence are combined. Application: Limitation: Hybridization occurs only when the bonds are being formed beofused toisexplain the Doesn't describe the ge Energy and the Can number orbitals conserved
bonding of molecules
of molecules
Hybridization: process of replacing pure atomic orbitals with reformulated atomic Atomic Orbital sp hybridization orbitals for bonded atoms
Hybridization
Hydrid Orbital: the new orbital Hybrid Orbitals Geometry
Example: BeCl2
Geometric Orientation Linear (V.B. Theory) Trigonal-planar Tetrahedral Atomic Orbital Trigonal-bipyramidal Hybridization Octahedral
Bonding
sp sp2 sp3 sp3d sp3d2
(VSEPR)
sp hybridizati
Example: BeCl
Geometry
Bonding
(VSEPR)
(V.B. Theory)
Geometry (VSEPR) Lewis structure
Example #1: sp hybridization BeCl2
.. Cl ..
Be
.. Cl ..
1. Draw Lewis Dot Diagram
1800
Geometry (VSE Lewis structure 2. Fill in s and p orbitals
.. Cl ..
Be
Linear molecule Cl 3s
.. Cl ..
.. Cl ..
Be
180 0
.. Cl ..
Cl 3s
3. Promote electron into the p orbital
Hybridization predicts two identical bonds, as expected!
2 Linear molecule
Cl 3s
Cl
3p Be sp
Cl 3s
3p
2p
11. 3 – Hybridization
Results in a two sp with p overlaps
Be 2p
2s
2p
Energy
Hybridization C
Be sp (2)
3 hybrid sp2 orbitals
2p
s
s
C
p
s
p
s
p
p (2)
+
sp2
sp2 sp2 (3)
Example #2: BF3 (Trigonal planar molecule) F
ess!
Success!
F 1s
2s
2p
1s
B
Hybridization predicts two identical bonds, as expected!
2p
B sp2
Results in three hybrid sp2 atomic orbital
2s
sp2
p
+ 2 more ..
3 equivalent
4 equivalent
p
bonds formed at 120o
bonds
H H F
p
C
C
H
F
sp2 sp2
sp2
F
F
F
p
B
B
H
120
0
F
p
2 hybrid sp orbitals 3 equivalent
s
bonds formed at 120o
p
9
One pure s orbital
Example #3: CH4 (Tetrahedral)
p
Three pure p orbitals
Energy + C s
p
Hybridization C
4
= C Four hybrid sp3 atomic orbitals s
p
sp3 (4)
Results in a four hybrid sp3 atomic orbital
4 equivalent
H
bonds
Cl Cl
P Cl
s Cl Cl
11. 3 – Hybridization
Example #4: PCl5 (Trigonal bipyramidal)
5 hy
P s
p
d
Hybridization sp3d (5)
d
Results in a one sp3d hybridization
One of f sp3d hyb orbitals
Example #5: SF6 (Octahedral)
Results in a sp2d2 hybrid orbital
Hybridization in Atoms with Lone Pairs N But actual bond angle is 107°
Example: NH3
2s
N
2p
11. 3 – Hybridization sp3 hybridization!
s
p
Hybridization
N sp3
Hybrization in Atoms with Lone Pairs: Example #5: NH3 p orbitals are perpendicular N
N
N
2s
2s
s
2p
p
Hybridization
2p
N
Suggests 3 bonds
sp3
1lone pair
H H
Multiple Bonds:
C CC
bond angles 390° bonding pairs H H H
C C
C
H
c
1s
H 1s
c
1s
H H
C C
18 1lone pair C
sp3
C
C CC
sp3 C
H
1s
C
sp
p
sp 1s
sp3
3
bonds
p-p side by sid 1s
sp3
p orbitals are perpendicular C
H H
C CC
H H
C C
H
C
C
C
C
90° bond angles
c
H
C
C
C sp
18
p-p side by side
C
H
Valence Bond Theory
Application: Can be used to explain the bonding of molecules
Limitation: Doesn't describe geometry 11. 3 –the Hybridization of molecules
Atom must go from ground state"Basic" to excited state by absorbing energy and "Basic" promoting an electron Valence Bond Theory Bond T The number of hybrid orbitals equals the total number of atomic orbitals thatValence are combined. Application: Limitation: Hybridization occurs only when the bonds are being formed beofused toisexplain the Doesn't describe the ge Energy and the Can number orbitals conserved
bonding of molecules
of molecules
Hybridization: process of replacing pure atomic orbitals with reformulated atomic Atomic Orbital sp hybridization orbitals for bonded atoms
Hybridization
Hydrid Orbital: the new orbital Hybrid Orbitals Geometry
Example: BeCl2
Geometric Orientation Linear (V.B. Theory) Trigonal-planar Tetrahedral Atomic Orbital Trigonal-bipyramidal Hybridization Octahedral
Bonding
sp sp2 sp3 sp3d sp3d2
(VSEPR)
sp hybridizati
Example: BeCl
Geometry
Bonding
(VSEPR)
(V.B. Theory)
Geometry (VSEPR) Lewis structure
Example #1: sp hybridization BeCl2
.. Cl ..
Be
.. Cl ..
1. Draw Lewis Dot Diagram
1800
Geometry (VSE Lewis structure 2. Fill in s and p orbitals
.. Cl ..
Be
Linear molecule Cl 3s
.. Cl ..
.. Cl ..
Be
180 0
.. Cl ..
Cl 3s
3. Promote electron into the p orbital
Hybridization predicts two identical bonds, as expected!
2 Linear molecule
Cl 3s
Cl
3p Be sp
Cl 3s
3p
2p
11. 3 – Hybridization
Results in a two sp with p overlaps
Be 2p
2s
2p
Energy
Hybridization C
Be sp (2)
3 hybrid sp2 orbitals
2p
s
s
C
p
s
p
s
p
p (2)
+
sp2
sp2 sp2 (3)
Example #2: BF3 (Trigonal planar molecule) F
ess!
Success!
F 1s
2s
2p
1s
B
Hybridization predicts two identical bonds, as expected!
2p
B sp2
Results in three hybrid sp2 atomic orbital
2s
sp2
p
+ 2 more ..
3 equivalent
4 equivalent
p
bonds formed at 120o
bonds
H H F
p
C
C
H
F
sp2 sp2
sp2
F
F
F
p
B
B
H
120
0
F
p
2 hybrid sp orbitals 3 equivalent
s
bonds formed at 120o
p
9
One pure s orbital
Example #3: CH4 (Tetrahedral)
p
Three pure p orbitals
Energy + C s
p
Hybridization C
4
= C Four hybrid sp3 atomic orbitals s
p
sp3 (4)
Results in a four hybrid sp3 atomic orbital
4 equivalent
H
bonds
Cl Cl
P Cl
s Cl Cl
11. 3 – Hybridization
Example #4: PCl5 (Trigonal bipyramidal)
5 hy
P s
p
d
Hybridization sp3d (5)
d
Results in a one sp3d hybridization
One of f sp3d hyb orbitals
Example #5: SF6 (Octahedral)
Results in a sp2d2 hybrid orbital
Hybridization in Atoms with Lone Pairs N But actual bond angle is 107°
Example: NH3
2s
N
2p
11. 3 – Hybridization sp3 hybridization!
s
p
Hybridization
N sp3
Hybrization in Atoms with Lone Pairs: Example #5: NH3 p orbitals are perpendicular N
N
N
2s
2s
s
2p
p
Hybridization
2p
N
Suggests 3 bonds
sp3
1lone pair
H H
Multiple Bonds:
C CC
bond angles 390° bonding pairs H H H
C C
C
H
c
1s
H 1s
c
1s
H H
C C
18 1lone pair C
sp3
C
C CC
sp3 C
H
1s
C
sp
p
sp 1s
sp3
3
bonds
p-p side by sid 1s
sp3
p orbitals are perpendicular C
H H
C CC
H H
C C
H
C
C
C
C
90° bond angles
c
H
C
C
C sp
18
p-p side by side
C
H
