H. Bursing et P. Vohringer, Transition state probing and fragment rotational dynamics following impulsive bond breakage of HgI2, PCCP PHYS C, 2(1), 2000, pp. 73-82
The optical anisotropic response following 30 fs, 266 nm photolysis of merc
uric diiodide in ethanol solution was measured to explore transition state
dynamics leading to bond fission as well as fragment rotational dynamics in
the asymptotic limit for two-body dissociation. The reactive motion in the
vicinity of the transition state is accompanied by modifications of the na
ture of the electronic transition utilized for optical detection. The initi
al motion away from the originally prepared Franck-Condon region through th
e transition state toward the fragments effectively rotates the transition
moment of the electronic probe resonance in the molecular frame of the dyna
mically evolving system. After the reactive portion including bond breakage
is complete, the anisotropy reveals an inertial component on ultrafast tim
e scales well below 1 ps. The time constant associated with this inertial d
ecay is much faster than the free-rotor time constant of HgI implying that
impulsive bond breakage of the parent molecule results in rotational excita
tion of the diatomic fragment. It is argued that excitation of fragment rot
ational degrees of freedom presumably arises from pronounced anisotropies o
f the excited state potential which is known to be bent for isolated HgI2.
Furthermore, coherent vibrational motion of the diatomic product gives rise
to periodic modulations of the anisotropy due to stretch-bend coupling in
the dynamically evolving system.