Alignment of the CS2 Dimer Embedded in Helium Droplets Induced by a Circularly Polarized Laser Pulse

Abstract

Dimers of carbon disulfide (CS2) molecules embedded in helium nanodroplets are aligned using a moderately intense, 160ps, non-resonant, circularly polarized laser pulse. It is shown that the intermolecular carbon-carbon (C-C) axis aligns along the axis perpendicular to the polarization plane of the alignment laser pulse. The degree of alignment, quantified by 2(θ2D) , is determined from the emission directions of recoiling CS2+ fragment ions, created when an intense 40fs probe laser pulse doubly ionizes the dimers. Here, θ2D is the projection of the angle between the C-C axis on the 2D ion detector and the normal to the polarization plane. 2(θ2D) is measured as a function of the alignment laser intensity and the results agree well with 2(θ2D) calculated for gas-phase CS2 dimers with a rotational temperature of 0.4K.