Effect of two-electron spin-orbit interactions on singlet-triplet transition probabilities

Abstract

Previously reported calculations concerned with spin-orbit enhancement of molecular S-T transitions have utilized an approximate one-electron spin-orbit Hamiltonian. The approximations are carried over from atomic spin-orbit theory and are justified on the basis of physical reasoning strictly applicable only to diagonal matrix elements. In order to test critically these assumptions, a treatment of spin-orbit enhancement of the formaldehyde ³ A ₂ ↔ ¹ A ₁ transition is given using the complete spin-orbit Hamiltonian. A one-electron approximation to the spin-orbit Hamiltonian is found to be conceptually valid. The one-electron approximation which most closely approximates the complete spin-orbit Hamiltonian is the bare nuclear field Hamiltonian. Calculations on the lowest triplet state of the azines yield similar results. The polarization of the formaldehyde ³ A ₂ ← ¹ A ₁ absorption is predicted to be almost solely along the C-O axis in agreement with the rotational experiments of Raynes. The predicted oscillator strength is 9 × 10^-8). To investigate consequences of relaxation to the triplet equilibrium configuration before phosphorescence from the triplet state a spin-orbit calculation on formaldehyde in the ³ A ₂ equilibrium configuration is carried out. It is not possible to predict whether the ³ A ₂ → ¹ A ₁ transition moment should be almost solely along the C-O axis or whether it should have an appreciable component perpendicular to the C-O axis (y in the figure) in addition to the C-O component. The probability of T ₁ → S ₀ is predicted to be ∼ 3 times T ₁ ← S ₀.