Quantum state-selected photodissociation dynamics in H2O and D2O

Abstract

Two photon excitation, tunable near 248·5 nm, has been used to dissociate H₂O/D₂O via the [Ctilde] ¹ B ₁ and [Btilde] ¹ A ₁ states. Rotationally resolved OH/OD(A ²Σ⁺) photofragment excitation spectra are reported, following excitation to predissociated levels of [Ctilde] ¹ B ₁. Rotational resolution of the OH/OD(A ²Σ⁺ → X ²Π) fluorescence, generated from individual J′ _{K a K c} levels of [Ctilde] ¹ B ₁, allows full quantum state selection in both the entry and exit channels. The OH/OD(A ²Σ⁺) fragment is formed rotationally hot as a result of the large change in bond angle in going from [Xtilde] ¹ A ₁ (or [Ctilde] ¹ B ₁) to the linear dissociative [Btilde] ¹ A ₁ surface. Product alignment measurements allow assignment of the two photon continuum absorption to [Btilde] ¹ A ₁: a-axis rotation in [Ctilde] ¹ B ₁ destroys product alignment from these levels. Electronic branching from ⪷B ¹ A ₁ to à ¹ B ₁ (and/or [Xtilde] ¹ A ₁) during the dissociation forms ground state OH/OD(X ²Π). Relative branching ratios are obtained and display a strong K′_a dependence.