Abstract
Unless the molecular axis is fixed in the laboratory frame, intrinsic structural information of molecules can be averaged out over the various rotational states. The macroscopic directional properties of polar molecules have been controlled by two fs pulses with an optimized delay. In the method, the first one-color laser pulse provokes molecular alignment. Subsequently, the molecular sample is irradiated with the second two-color laser pulse, when the initial even—J states are aligned, and the odd—J states are anti-aligned in the thermal ensemble. The second pulse selectively orients only the aligned even—J states in the same direction, which results in significant enhancement of the net degree of orientation. This paper reports the results of simulations showing that the two-pulse technique can be even more powerful when the second pulse is cross-polarized. This study shows that the alignment and orientation can be very well synchronized temporally because the crossed field does not disturb the preformed alignment modulation significantly, suggesting that the molecules are very well confined in the laboratory frame. This cross-polarization method will serve as a promising technique for studying ultrafast molecular spectroscopy in a molecule-fixed frame.
Highlights
In recent decades, laser-based techniques for fixing molecules in space have become an important tool for a range of experiments
While the state-selection has provided the highest degree of orientation far, the all-optical two-pulse technique is more suitable for the high-order harmonic generation experiment because of the available high target density[33,34,35]
We show that a two-color field with crossed polarization can improve the field-free orientation of linear molecules, by solving the time-dependent Schrödinger equation (TDSE) numerically in the shortpulsed crossed polarization regime for the first time
Summary
Laser-based techniques for fixing molecules in space have become an important tool for a range of experiments. The interaction Hamiltonian induced by the crossed polarization of a two-color field was derived, and it was demonstrated that it could enhance the degree of orientation of linear molecules in the quasi-adiabatic condition[39].
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