1) I dont have very strong physical chemistry backgroud(though i really love physical chemistry LOL) so i dont really understand what do you mean configuration interaction:
"Configuration interaction causes additive and subtractive mixing of transition probabilities"
The weak and strong pi-pi* transitions of porphine i think should be govern by the change in orbital angular momentum?
Bear in mind, configuration interaction is a theoretical construct. But, more or less it refers to the fact that electronic wavefunctions can mix if they have the appropriate symmetry, and when they do so, you get linear combinations (i.e., additive or subtractive). In the case of porphyrin, you have two sets of two nearly degenerate transitions between the two homo and two lumo orbitals. One of these pairs is polarized in the x-direction and the other in the y-direction. So what you get is basically two x-polarized transitions of practically the same energy that are fully allowed. However if we allow for transitions/states of appropriate symmetry to mix, you get basically additive and subtractive combinations of these states. The additive combination becomes even more allowed and is blue-shifted, and the subtractive combination becomes partially forbidden and is red-shifted. You'd have to play around with the transition moment integral to see why that's the case, but effectively this is why porphyrin optical spectra exhibit a low energy, partially forbidden set of pi-pi* bands (often called the Q-bands) and a higher energy, fully allowed transition (called the B- or Soret-band). Any substitution to the porphyrin macrocycle breaks the degeneracy of the HOMO and LUMO orbitals, resulting in a poorer degree of mixing, and therefore an increase in the intensity of the Q-band. This mixing is what we can casually refer to as "configuration interaction" - the interaction between two potential electron configurations. It is certainly a peculiarity of quantum mechanics. In a classical world, the electron configuration would have to be one or the other. In the quantum world, it's both at the same time. In fact, it is not so dissimilar from the quantum double slit experiment, where an electron basically interferes with itself.
Anyway, this type of CI manifests in most very symmetric pi-conjugated molecules. Which is why for the most symmetric molecules - e.g., benzene - the lowest energy optical transition actually has very low extinction coefficient, despite being what would appear to be a fully allowed pi-pi* transition.
A lot of theoretical research in the 1960s and beyond was on ways to calculate the effects of configuration interaction to better predict energy levels of organic molecules.
I was having this question cuz i was told that partial hydrogenation of porphyrin to give chlorin may have the molar absorptivity increase by 8 times, which suprize me alot. Do you have any explanation for this observation?
I am not familiar with the electronic absorption spectra of chlorin, but given that it has less symmetry than porphine, I could see have it may have stronger molar absorptivity.
2) I understand that the pi to pi* excitation are governed by frank condon principle but i dont understand why "the rate of non-raditative decay is dominated by vibronic coupling between the ground electronic state and the emissive excited electronic state". Would you mind elaborate abit more?
If you don't mind, I will postpone answering this until tomorrow. I have a nice figure that illustrates it better than I can describe with words alone.
3) For simple heterocyclics like pyridine and furan dont exhibit fluorescence, you comment that "the predominant theory is that heteroatoms have non-bonding electrons, and as such have low-lying n π* transitions that effectively short-circuit the excite state before fluorescence can occur molecules with larger energy gaps have slower non-radiative rate constants"
Do you mean that the quenching is done by something similar to FRET? (ie: the pi to pi* electron in excited state singlet state relax to ground state and excite the electron from n to pi* triplet?)
So do you mean that open-shell metal ions can quench fluorescence by d-d transition instead of n to pi* in porphyrins?
Again, I think the figure I will show you tomorrow will help. But basically any time you introduce lower energy molecular states that provide an avenue for excited-state relaxation, this will tend to reduce the excited state lifetime, and hence the fluorescence yield. It's kind of like this: imagine you are a part of a hiking group that has walked to a cliff, and the tour guide tells you all that you've got to get to the bottom to finish the tour. But: there's only one way down: jumping. You stand up there and look over the edge, there's a pond at the bottom that your guide promises you is deep enough to make jumping safe, but even so maybe it takes the average person quite a long time to work up the nerve to just throw themselves out into free fall. The total amount of time it takes for the group to get to the bottom is long. Now imagine the same scenario but there's a couple of smaller ledges between you and the ground below, such that you can hop down gradually. Don't you imagine that the total time to get to the bottom now will be a much less? Sure, some thrill seekers may still jump, but most people will opt for the safer route.
I hope this analogy is clear. d-d states, n-pi states, and so forth, are all little ledges that allow electrons to quickly get back down to the ground state, but they don't emit photons when they relax this way. So, they take away from the fluorescence yield of the molecule.
btw, why is that fused ring fluorescence heterocycles wont have this quenching problem?
My guess would be that whereas pi-pi* transitions are highly delocalized, n-pi* transitions are less so. The coupling between states is to some degree dependent on geometry. So the coupling between pi-pi* transition and n-pi* transition in pyridine is good, it is less good as the pi system becomes larger. Porphine is also a heteroatom system, but it has a reasonable fluorescence yield. There is also the matter of whether there is electron density on the heteroatom. In simple symmetric systems the electron density on each position is identical, but this is not the case in more complicated ring systems.
(This is also, by the way, one of the reasons why the triplet yield goes down in conjugated polymers, because singlet states tend to be highly delocalized, whereas triplet states are not. So, you get poor spatial coupling between the triplet and singlet wavefunctions as the number of conjugated repeat units increases.)
7) For organic molecule pi to pi* transition (in uv-vis spectrum), the major absorption peak is quite broad usually (across 100 nm). so my question is why the absorption peak isnt a sharp peak instead?
Lifetime broadening is one part of it. But, organic molecules also have a lot of conformational freedom - even fairly rigid ones, which broadens out transitions. Finally, most of this work is done in solution phase. The possible solvent interactions with the fluorophore also contribute to broadening mechanisms. If you do low-temperature (77K) experiments, you will see these transitions narrow up quite a bit, because less favorable conformations are removed from the equation.
8 ) A lot of organic compounds may undergo rapid ISC to triplet state and have the fluorescence quenched. So i am just curious to know why it is not common for them to undergo phosphorescence after ISC?
Meanwhile, Ru(bpy)32+ make use of spin orbit coupling to give triplet excited state and eventually have phosphorescence. so why Ru-bpy type molecule could achieve such luminescence while lots of molecule couldnt?
Metal polypyridyl complexes are sort of hybrid species. The low-lying electron states are not pi-pi* transitions. They are metal-to-ligand charge transfer transitions. Formally we call them singlets and triplets, but this terminology is really most meaningful when the two electrons have the same spatial delocalization. In the case of an MLCT transition, one of the electrons has been transferred away from the metal center and is located on a ligand. There is still some interaction between these electrons, particularly in ru-bpy, because of their close proximity, but I don't think it's appropriate to call it a true triplet state, either. The lifetimes of true triplet states are generally in the hundreds of microseconds or even longer. The MLCT states of ru(bpy)
3 are only in the low microsecond range.
As to why phosphorescence isn't common. Well, if the intersystem crossing rate from excited singlet to excited triplet is fast, generally so to is the intersystem crossing rate from the excited triplet back to the ground singlet. Also, oxygen (a ground state triplet) does a good job of quenching triplet states of organic molecules because it turns this into a spin-allowed process. The diffusion limited process is on the order of a microsecond at room temperature, meaning that unless the triplet state is lower in energy than that of singlet oxygen, or the radiative rate is faster than a microsecond, you're going to quench your phosphorescence pretty efficiently. So, you often don't observe phosphorescence unless your solution is deoxygenated, and even then you may not see it because competitive nonradiative decay is fast.