Long range behavior of the gerade states near the 2P3/2+ 2P3/2 iodine dissociation limit by laser-induced-fluorescence Fourier-transform spectroscopy

Abstract

The near infrared LIF–FTS spectra from the I₂ B 0_u⁺ state, excited by an argon ion laser and recorded by a high resolution Fourier‐transform spectrometer, contain information about perturbations between the gerade states converging to the I₂→2I(²P_3/2) dissociation limit. The observed perturbation interactions are sampled at internuclear distances near 5 Å and are interpreted in a separated atom (I₂=I_a+I_b; ψ_I2=φ_aφ_b; φ_a=‖ j_a=3/2, m_a〉) basis set. Near r=5 Å the X 0_g⁺ and a′ 0_g⁺ states are found to have predominant m_a=−m_b=±1/2 and m_a=−m_b=±3/2 character, respectively, but with slight ‖m‖=1/2∼‖m‖=3/2 mixing. In this pure ‖m‖ basis, S=s_a+s_b and J_atomic=j_a+j_b are not well defined, but in the limit of complete ‖m‖=1/2∼‖m‖= 3/2 mixing, S and J_atomic are well defined. The behavior of three gerade states (X 0_g⁺, a′ 0_g⁺, a 1_g) at large internuclear distance has been analyzed using the long range theory of LeRoy and Bernstein. The results are in fair agreement with theoretical predictions, and give a direct and precise determination of the X state well depth, D⁰₀=12 440.083±0.145 cm⁻¹.