Hybridization was introduced to explain molecular structure
when the valence bond
theory failed to correctly predict them. It is experimentally observed
that bond angles in organic compounds are close to 109o, 120o, or 180o. According
to Valence Shell Electron Pair Repulsion (VSEPR) theory, electron
pairs repel each other and the bonds and lone pairs around a central atom are
generally separated by the largest possible angles. Carbon is a perfect example
showing the need for hybrid orbital’s.
According to Valence Bond
Theory, carbon should form two covalent bonds, resulting in a CH2,
because it has two unpaired electrons in its electronic configuration. However,
experiments have shown that CH2CH2 is highly reactive and cannot
exist outside of a reaction. Therefore, this does not explain how CH4 can
exist. To form four bonds the configuration of carbon must have four unpaired
electrons. The only way CH4 it can be explained is, the 2s and the 3 2p
orbitals fused together to make four, equal energy sp3 hybrid
orbital’s. Now that carbon has four unpaired electrons it can have four
equal energy bonds. The hybridization of orbitals is also greatly favored
because hybridized orbitals are lower in energy compared to their separated, hybridized counterparts. This results in more stable compounds when
hybridization occurs. Also, major parts of the hybridized orbitals, or the
frontal lobes, overlap better than the lobes of hybridized orbitals. This
leads to better bonding.
The next topics will explain the various types of
hybridization and how each type helps explain the structure of certain
molecules.
sp3 hybridization
sp3 hybridization can explain the tetrahedral structure
of molecules. In it, the 2s orbitals and all three of the 2p orbitals hybridize
to form four sp orbitals, each consisting of 75% p character and 25% s
character. The frontal lobes align themselves in the manner shown below. In
this structure, electron repulsion is minimized.
Hybridization of an s orbital with all three p orbital results
in four sp3 hybrid orbitals. sp3 hybrid orbitals are oriented at bond
angle of 109.5o from each other. This 109.5oarrangement gives tetrahedral
geometry (Figure 4).
Example:
sp3 Hybridization in Methane
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Because carbon plays such a significant role in organic
chemistry, we will be using it
as an example here. Carbon's 2s and all three of its 3p
orbitals hybridize to form four sp3 orbitals.
These orbitals then bond with four hydrogen atoms through
sp3-s orbital overlap, creating methane.
The resulting shape
is tetrahedral, since that minimizes electron repulsion.
Hybridization
Lone Pairs: Remember to take into account lone pairs
of electrons.
These lone pairs cannot double bond so they are placed in
their own hybrid orbital.
This is why H2O is tetrahedral.
We can also build sp3d and sp3d2 hybrid
orbitals if we go beyond s and p sub-shells.
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sp2 hybridization
sp2 hybridization can explain the trigonal planar
structure of molecules. In it, the 2s orbitals and two of the 2p orbitals
hybridize to form three sp orbitals, each consisting of 67% p and 33% s
character. The frontal lobes align themselves in the trigonal planar structure,
pointing to the corners of a triangle in order to minimize electron repulsion
and to improve overlap. The remaining p orbital remains unchanged and is
perpendicular to the plane of the three sp2 orbitals.
Example:
sp2 Hybridization in Aluminum Trihydride
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In aluminum trihydride, one 2s orbital and two 2p orbitals
hybridize to
form three sp2 orbitals that align themselves in the
trigonal planar structure.
The three Al sp2 orbitals bond with with 1s orbitals
from the three hydrogens
through sp2-s orbital overlap.
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Example:
sp2 Hybridization in Ethene
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Similar hybridization occurs in each carbon of ethene. For
each carbon, one 2s orbital
and two 2p orbitals hybridize to form three sp2 orbitals.
These hybridized orbitals align
themselves in the trigonal planar structure. For each
carbon, two of these sp orbitals
bond with two 1s hydrogen orbitals through s-sp orbital
overlap. The remaining sp2 orbitals
on each carbon are bonded with each other, forming a bond
between each carbon through
sp2-sp2 orbital overlap. This leaves us with the two
p orbitals on each carbon that
have a single carbon in them. These orbitals form a ?
bonds through p-p orbital
overlap, creating a double bond between the two carbons.
Because a double bond
was created, the overall structure of the ethene compound
is linear. However,
the structure of each molecule in ethene, the two carbons,
is still trigonal planar.
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sp Hybridization
sp Hybridization can explain the linear structure in
molecules. In it, the 2s orbital and one of the 2p orbitals hybridize to form
two sp orbitals, each consisting of 50% s and 50% p character. The front lobes
face away from each other and form a straight line leaving a 180° angle between
the two orbitals. This formation minimizes electron repulsion. Because only one
p orbital was used, we are left with two unaltered 2p orbitals that the atom
can use. These p orbitals are at right angles to one another and to the line
formed by the two sp orbitals.
These p orbital’s come into play in compounds such as ethyne
where they form two addition? bonds, resulting in in a triple bond. This only
happens when two atoms, such as two carbons, both have two p orbitals that each
contain an electron. An sp hybrid orbital results when an s orbital is combined
with p orbital (Figure 2). We will get two sp hybrid orbitals since we started
with two orbitals (s and p). sp hybridization results in a pair of directional
sp hybrid orbitals pointed in opposite directions. These hybridized orbitals
result in higher electron density in the bonding region for a sigma bond toward
the left of the atom and for another sigma bond toward the right. In addition,
sp hybridization provides linear geometry with a bond angle of 180o.
Example:
sp Hybridization in Magnesium Hydride
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In magnesium hydride, the 3s orbital and one of the 3p
orbitals from magnesium
Hybridize to form two sp orbitals. The two frontal lobes
of the sp orbitals face away from
Each other forming a straight line leading to a linear
structure. These two sp orbitals bond
With the two 1s orbitals of the two hydrogen atoms through
sp-s orbital overlap.
Hybridization
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An easy way to figure out what hybridization an atom has is
to just count the number of atoms bonded to it and the number of lone pairs. Double
and triple bonds still count as being only bonded to one atom. Use this method
to go over the above problems again and make sure we understand it. It's a lot
easier to figure out the hybridization this way.
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