Coherent Control of the Rotation Axis of Molecular Superrotors

TL;DR

This paper theoretically demonstrates a method to coherently control the rotation axes of molecular superrotors, specifically H₂S, using an optical centrifuge with tailored pulse envelopes, enabling stable rotation about different molecular axes.

Contribution

It introduces a novel scheme to control molecular rotation axes using optical centrifuge pulses, advancing ultrafast rotational control techniques for asymmetric-top molecules.

Findings

Achieved stable rotation about two different molecular axes.

Controlled the angular momentum alignment of molecules.

Manipulated rotational states via tailored optical centrifuge pulses.

Abstract

The control of ultrafast molecular rotational motion has benefited from the development of innovative techniques in strong-field laser physics. Here, we theoretically demonstrate a novel type of coherent control by inducing rotation of an asymmetric-top molecule about two different molecular axes. An optical centrifuge is applied to the hydrogen sulfide (H$_2$S) molecule to create a molecular superrotor, an object performing ultrafast rotation about a well-defined axis. Using two distinct pulse envelopes for the optical centrifuge, we show that H$_2$S can be excited along separate pathways of rotational states. This leads to stable rotation about two entirely different molecular axes while ensuring rotation is about the propagation direction of the centrifuge, i.e., the laboratory-fixed $Z$-axis. The presented scheme to control the angular momentum alignment of a molecule will, for instance, be useful in studies of molecule-molecule or molecule-surface scattering, especially due to the large amounts of energy associated with superrotors, which can even be controlled by changing the duration of the optical centrifuge pulse.