Finding Bond Angles Shapes And Hybridizations

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Finding Bond Angles, Shapes, and Hybridizations
Gettin' funky, VSEPR style
Sometimes people have a hard time with the whole VSEPR thing. In this helpdesk section we'll
discuss what VSEPR means, what it's all about, and how you can use a great big flow chart to figure
out the bond angles, shapes, and hybridizations of various covalent compounds.
What is VSEPR?
VSEPR stands for Valence Shell Electron Pair Repulsion. It's a complicated acronym, but it means
something that's not difficult to understand. Basically, the idea is that covalent bonds and lone pair
electrons like to stay as far apart from each other as possible under all conditions. This is because
covalent bonds consist of electrons, and electrons don't like to hang around next to each other much
because they have the same charge.
This VSEPR thing explains why molecules have their shapes. If carbon has four atoms stuck to it (as
in methane), these four atoms want to get as far away from each other as they can. This isn't
because the atoms necessarily hate each other, it's because the electrons in the bonds hate each
other. That's the idea behind VSEPR.
What is hybridization?
Now, one problem with the whole VSEPR thing is that if you have four things stuck to carbon, for
example, there are no orbitals that want to get 109.5 degrees apart from each other (109.5 degrees
corresponds to the geometric maximum distance the atoms can get apart). After all, s-orbitals go in a
complete sphere (360 degrees) and p-orbitals are 90 degrees apart.
What happens instead of using s- or p- orbitals is that when covalent bonds are formed, the s- and p-
orbitals mix to form something called hybrid orbitals. "Hybrid" just means "mixture of two different
things", and that's exactly what a hybrid orbital is. When three p-orbitals with 90 degree angles
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combine with one s-orbital with 360 degrees, they average to form four sp
orbitals with 109.5 degree
bond angles. Depending on the numbers of s- and p-orbitals that mix, you can get a bunch of
different bond angles.
Common shapes you should know
There are a whole bunch of common shapes you need to know to accurately think of covalent
molecules. Here they are:
Tetrahedral: Tetrahedral molecules look like pyramids with four faces. Each point on the
pyramid corresponds to an atom that's attached to the central atom. Bond angles are 109.5
degrees.
Trigonal pyramidal: It's like a tetrahedral molecule, except flatter. It looks kind of like a
squished pyramid because one of the atoms in the pyramid is replaced with a lone pair. Bond
angles are 107.5 degrees (it's less than tetrahedral molecules because the lone pair shoves
the other atoms closer to each other).
Trigonal planar: It looks like the hood ornament of a Mercedes automobile, or like a peace
sign with that bottom-most line gone. The bond angles are 120 degrees.
Bent: They look, well, bent. Bond angles can be either 118 degrees for molcules with one
lone pair or 104.5 degrees for molecules with two lone pairs.

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