Are there any advantanges to VB theory over MO theory?

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Valence Bond (VB) theory offers explanations for certain molecular phenomena that Molecular Orbital (MO) theory cannot, particularly in the case of the F2 molecule's stability and the application of resonance structures in coordination complexes. While VB theory is generally more accurate than Hartree-Fock calculations, it becomes cumbersome for metallic compounds like Boranes due to the need for numerous resonance structures. Key examples where MO theory excels include back-bonding in carbonyl metal complexes and the explanation of cycloadditions through molecular orbital phases.

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Are there any things that can be explained by valence bond theory, that cannot be explained by molecular orbital theory? I know of various things that can only be explained by MO theory, and not VB theory, but does it go both ways?
 
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Yes, e.g. VB yields a molecule F2 while it isn't stable in Hartree Fock theory.
I don't think there are many things that can't be explained in VB theory but only in MO theory.
However, VB theory becomes cumbersome when you use it in metallic or semi-metallic componds
like Boranes as you need an excessive number of resonance structures.
Generally, VB calculations are much more accurate than Hartree Fock calculations but also much more
costly in terms of computing power.
 
One case that I know of that can be explained only by MO theory, are back bonding in carbonyl metal complexes (the C=O bond gets weakened by electron donation from the metal, AFAIK this can only be explained by considering antibonding orbitals). Another example is cycloadditions, i.e. you can explain why photoexcited 2 + 2 cycloadditions work, by considering the phases of the MOs. Maybe these things can be explained by VB theory too, I haven't put too much thought into it.
 
Thanks. Yeah, resonance structures explain it pretty simply alright. I didn't know resonance structures applies to coordination complexes like that. That'll help me a lot in understanding the properties of various complexes, thanks a lot.
 

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