The photodissociation dynamics of chlorine azide (ClN(3)) at the 157 nm region was studied theoretically using the multireference configuration interaction method and the complete active space self-co Show more
The photodissociation dynamics of chlorine azide (ClN(3)) at the 157 nm region was studied theoretically using the multireference configuration interaction method and the complete active space self-consistent field direct dynamics method. The excitation at the 157 nm region was assigned to the 4 (1)A(')(S(7))<--X (1)A(')(S(0)) transition. A likely pathway for the formation of cyclic N(3) after this transition was identified by direct dynamics as follows: ClN(3) excited to 4 (1)A(')(S(7)) dissociates after about 40 fs to excited N(3)(2 (2)A('), with about 44 kcal/mol internal energy) +Cl((2)P). This vibrationally hot N(3)(2 (2)A(')) goes diabatically through a conical intersection with N(3)(1 (2)A(')) at 44 fs onto 1 (2)A('). At 19 fs later and repeatedly after every 55 fs, N(3)(1 (2)A(')) crosses and trickles down via Coriolis coupling to N(3)(2 (2)A(")/ (2)B(1)) state, which has a potential minimum at the cyclic-N(3) structure. Some fraction of N(3)(2 (2)A(")/ (2)B(1)) produced will survive dissociation and will be found as the cyclic N(3), and some other fraction will eventually dissociate to N((2)D)+N(2) over a high barrier found previously. Show less