The photodissociation of UF6 using infrared lasers

The spectral d~st~bution of phot~~ss~iation yield is measured following UF, excitation in the B band. Dissociation is not uniform, confirming previous results obtained by an entirely different method. The experimentat conditions imposed by the laser snow technique employed in this work may account f

Multiphoton ionization of UF s as a probe of laser-induced dissociation of UF 6 is investigated using an ionization chamber. Results are given on the fluence dependence of the multiphoton ionization process and on the pressure dependence of the UF 6 photodissociation.

UF5 molecules were produced from laser photolysis of very 101% pressure samples of UFh in a long path cell. The pxtlai infmed absorprion spectrum of the initially formed UFS molecule was recorded in the 17 pm region. The elrent of internd vibrational excitation of the formed molecule and its lifetim

The draoswon weld oi UF6 ewted at 380 nm is studled on vvymg the pressure and the mass of ;1 colhsisional monoatomic p~~~tncr It is found that dlaoci3tlon IS colhsion-induced md that the dissociation yield incIe%es ~101 larger COULDs,on pxrncrs. An custmg kmehc mode: uiew~trl-state dynzunics IS disc

UFs undergoes decomposition m the presence of SF6 when mixtures of both are madiated wrth a TEA CO2 laser. The mechanism for UFe decomposition may involve vrbrational energy transfer from excited SF, and laser absorption from the same laser pulse by excited UFe in its vibrational quasi-continuum \*