The idea was to follow the excited state proton transfer through the water network by dynamics simulations. And actually what was found is that there are two possibilities: either a direct intramolecular proton transfer, which is known from aprotic solvents; but also proton transfer through the network.
The work was down by Nawee Kungwan who was a guest at our institute some time ago. My involvement was mostly through technical support and discussions, and by doing some early test calculations.
I was complaining about how constantly applying for grants is too tedious and may drive people out of science. But I also just remembered what I don't like in corporate life: suits. It's not so much that I mind spending ten minutes in the morning to make sure that I have a clean shave and that everything fits. It is that being "a suit" is really a whole different life style. Especially when it comes to transportation: Can I hop on my bike and cycle to work if I want to? No. Can I run home from work? Yes, but it is a logistical masterpiece. Can I just go somewhere after work and relax? Yes, but I'd have to be really careful.
If wearing a suit would be immediately related to productivity, I could see why wearing one makes sense. But doing all this just for appearance seems kind of unnecessary to me. So I am happy, I don't have to do that, at least.
The LUMO (which also corresponds to the first excited state) is a diffuse s-type orbital.
The next three orbitals (yielding the next three states) are of p-type character. The first one is antisymmetric with respect to the molecular symmetry plane (i.e. it is of a" character).
And two more p-type orbitals follow in the other spatial directions.
.plt files but use a non-standard larger grid.$pointval mo 23-30
grid1 vector 1 0 0 range -15,15 points 200
grid2 vector 0 1 0 range -15,15 points 200
grid3 vector 0 0 1 range -15,15 points 200
