Disentangling the Role of Bound-Bound and Bound-Continuum Transitions in Multiphoton Photoelectron Circular Dichroism of Limonene

Photoionisation of randomly oriented chiral molecules with circularly polarised light leads to a strong forward/backward asymmetry in the photoelectron angular distribution. This chiroptical effect, referred to as Photoelectron Circular Dichroism (PECD), was shown to take place in all ionisation regimes, from single photon to tunnel ionisation. In the Resonance Enhanced Multiphoton Ionisation (REMPI) regime, where most of the table-top PECD experiments have been performed, understanding the role of the intermediate resonances is currently the subject of experimental and theoretical investigations. In an attempt to decouple the role of bound-bound and bound-continuum transitions in REMPI-PECD, we photoionise the (+)-limonene enantiomer using two-color laser fields in [1+1'] and [2+2'] ionisation schemes, where the polarisation state of each color can be controlled independently. We demonstrate that the main effect of the bound-bound transition is to break the sample isotropy by orientation-dependent photoexcitation, in agreement with recent theoretical predictions. We show that the angular distribution of PECD strongly depends on the anisotropy of photoexcitation, which is different for circularly and linearly polarised laser pulses. On the contrary the helicity of the pulse that drives the bound-bound transition is shown to have negligible effect on the PECD.