The OH state-resolved angular momentum polarization generated by the H + N2
O reaction has been investigated at a mean collision energy of 1.5 eV. The
data were obtained under room temperature bulb conditions using 225 nm phot
olysis of H2S to generate translationally excited H atoms, and employed Dop
pler-resolved laser induced fluorescence to probe the nascent OH reaction p
roducts. The measurements revealed the OH rotational angular momentum, j',
to be aligned in the scattering plane (i.e., in the plane containing the re
actant and product relative velocity vectors, k and k'). Furthermore, j' wa
s found to be preferentially aligned parallel to k', particularly for lower
OH rotational states. Out-of-plane torsional forces have been shown, there
fore, to play an important role in generating OH rotation as the fragments
separate. The new data are discussed in light of previously published studi
es of the title reaction, both from our own laboratory, and from those of o
ther workers. Insight into the reaction mechanism is provided by comparison
with the photodissociation dynamics of HN3, which helps, in particular, to
clarify the origin of the propeller-like OH rotational angular momentum po
larization. (C) 2000 American Institute of Physics. [S0021-9606(00)01132-6]
.