Particle transport in dusty plasma ratchet structure
Abstract
Dusty plasmas and Feynman ratchets belong to two distinct fields of study. In dusty plasmas, charged particles can form a strongly coupled and weakly damped subsystem, exhibiting transport phenomena such as shear flow and vortices due to internal instabilities or external field control. Feynman ratchets, with their inherent asymmetry, can rectify random perturbations in non-equilibrium environments into directed particle transport. By adjusting experimental conditions, particle transport can be variously controlled. However, previous studies on particle transport in Feynman ratchets have been limited to overdamped and weakly coupled cases. By integrating the two disciplines of dusty plasma and the Feynman ratchet, a dusty plasma ratchet device can be designed. This approach not only offers a new method for effectively controlling charged particles in dusty plasmas but also extends the study of Feynman ratchets to the realm of strongly coupled and weakly damped systems. This study reviews recent experimental phenomena and rectification mechanisms of particle transport in dusty plasma ratchets, as well as their applications in particle separation.
