| This dissertation discusses the ultraviolet photodissociation dynamics and compares important molecular properties of the group-V hydrides (NH 3, PH3, SbH3, and BiH3). High- n Rydberg time-of-flight (HRTOF) spectroscopy has been used to study the 193.3 nm photolysis of AsH3. The center-of-mass (c.m.) translational energy distribution for the one-photon process, AsH3 + hv → AsH2 + H, P(Ec.m.), indicates that AsH2 internal excitation accounts for ∼ 64% of the available energy [i.e., hv − D 0(H2As-H)]. Secondary AsH2 photodissociation also takes place. Analyses of superimposed structure atop the broad P( Ec.m.) distribution suggest that AsH2 is formed with significant a-axis rotation as well as bending excitation. Comparison of the results obtained with AsH3 versus those of the lighter group-V hydrides (NH3, PH3) lends support to the proposed mechanisms. Of the group-V hydrides, AsH3 lies intermediate between the nonrelativistic and relativistic regimes, requiring high-level electronic structure theory.;The room temperature absorption spectrum of SbH3 has been recorded. The absorption spectrum is a broad continuum with no discernible structure; however, a long-wavelength tail is evident. The HRTOF technique has also been used to investigate the photodissociation dynamics of SbH 3 following 193.3 nm photolysis. The overall shapes of the translational energy distributions were inconsistent, precluding confident analysis. In spite of this, it is apparent that SbH2 products are formed with substantial internal excitation and secondary photodissociation occurs. These general observations are consistent with the results obtained for AsH 3. |
