Question

How do the bond angles compare for `"ClO"_2`, `"ClO"_2^(-)`, and `"Cl"_2"O"`? Explain why.

Answer 1

I got a questionable result, based on two sources giving me borderline bond angles.

`stackrel(117.40^@)overbrace("ClO"_2) > stackrel(~~111^@)overbrace("ClO"_2^(-)) > stackrel(110.88^@)overbrace("Cl"_2"O"),`

if the bond angle in `"ClO"_2^(-)` is about `111^@`.

`stackrel(117.40^@)overbrace("ClO"_2) > stackrel(110.88^@)overbrace("Cl"_2"O") > stackrel(~~110^@)overbrace("ClO"_2^(-)),`

if the bond angle in `"ClO"_2^(-)` is about `110^@`.

It's just too close to be sure either way unless your book has more precise bond angles in the answer key.

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For reference, the electronegativity of `"Cl"` is `3.16`, and that of `"O"` is `3.44`.

• `"Cl"_2"O"` has oxygen at the center (with chlorine having its typical valency as a halogen), and has `7+7+6 = 20` total valence electrons to distribute. The major resonance structure is:

Since oxygen is more electronegative, the negative electron density is mostly concentrated onto oxygen, which is closer to each bonding-electron pair (the electron density is closer together when you look near oxygen).

Therefore, oxygen's share of electron density repels the bonding-electron pairs more easily in each `"Cl"-"O"` bond than if the electronegativity difference was smaller.

This competes with the lone-pair repulsion, which would have contracted the bond angle...

Overall, the competing effects stack to increase the bond angle to a bit more than the expected `109.5^@`, because...

Its actual bond angle is about `color(blue)(110.88^@)`.

• `"ClO"_2` has `7+6+6 = 19` total valence electrons to distribute (yes, it's paramagnetic). The major resonance structure is:

With two double bonds, the bonding-electron pairs repel each other more so than with comparable single bonds, increasing the bond angle above the standard `109.5^@`.

Since `"O"` atom is larger than `"Cl"` atom, that also contributes to the substantially larger bond angle than in `"Cl"_2"O"`.

We also have the one less valence electron on `"Cl"` than in `"ClO"_2^(-)`, giving less "lone-pair" repulsion, and thus less contraction of the `"O"="Cl"="O"` bond angle by the `"Cl"` valence electrons, relative to one more valence electron on `"Cl"`. This further increases the bond angle.

Its actual bond angle is about `color(blue)(117.40^@)`.

• `"ClO"_2^(-)` has `7+6+6+1 = 20` total valence electrons to distribute. The major resonance structure is:

The bond order of each `"Cl"stackrel(--" ")(_)"O"` bond in the resonance hybrid structure (roughly `1.5`) is lower than the bond order in each `"Cl"="O"` bond in `"ClO"_2` (pretty much `2`).

Therefore, there is less electron density in each `"Cl"stackrel(--" ")(_)"O"` bond, allowing the ion's `"O"-"Cl"-"O"` bond angle to contract a little, relative to the same bond angle in `"ClO"_2`.

However, the fourth valence electron on `"Cl"` contracts the bond angle relative to `"ClO"_2` even more than if there were only three nonbonding valence electrons on `"Cl"`. How much smaller of a bond angle we get, I'm not sure.

I cannot find a more precise actual bond angle than `111^@`.

However, this source unfortunately lists a poor-precision angle of `110^@ pm 2^@`, which adds some confusion.

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Therefore, the bond angle order is questionable.

`color(blue)(stackrel(117.40^@)overbrace("ClO"_2) > stackrel(~~111^@)overbrace("ClO"_2^(-)) > stackrel(110.88^@)overbrace("Cl"_2"O")),`

if the bond angle in `"ClO"_2^(-)` is about `111^@`.

`color(blue)(stackrel(117.40^@)overbrace("ClO"_2) > stackrel(110.88^@)overbrace("Cl"_2"O") > stackrel(~~110^@)overbrace("ClO"_2^(-))),`

if the bond angle in `"ClO"_2^(-)` is about `110^@`.

It's just too close to be sure either way unless your book has more precise bond angles in the answer key.