Transverse ac Driven and Geometric Ratchet Effects for Vortices in Conformal Crystal Pinning Arrays

TL;DR

This paper demonstrates a novel transverse ratchet effect for vortices in conformal crystal arrays, driven by ac or dc forces, with the effect arising from non-Gaussian velocity fluctuations and showing reversals based on system parameters.

Contribution

It introduces a new type of transverse ratchet effect driven by non-Gaussian fluctuations in conformal arrays, distinct from previous mechanisms.

Findings

Transverse ratchet effect is more pronounced in conformal arrays.

Reversals in ratchet direction occur with changing parameters.

Drift ratchet outperforms ac ratchet in efficiency.

Abstract

With a series of conformal arrays it is possible to create asymmetric substrates, and it was previously shown that when an ac drive is applied parallel to the asymmetry direction, a pronounced ratchet effect occurs with a net dc flow of vortices in the same direction as the ac drive. Here we show that when the ac drive is applied perpendicular to the substrate asymmetry direction, it is possible to realize a transverse ratchet effect where a net dc flow of vortices is generated perpendicular to the ac drive. The conformal transverse ratchet effect is distinct from previous versions of transverse ratchets in that it occurs due to the generation of non-Gaussian transverse vortex velocity fluctuations by the plastic motion of vortices, so that the system behaves as a noise correlation ratchet. The transverse ratchet effect is much more pronounced in the conformal arrays than in random gradient arrays, and is absent in square gradient arrays due the different nature of the vortex flow in each geometry. We show that a series of reversals can occur in the transverse ratchet effect due to changes in the vortex flow across the pinning gradient as a function of vortex filling, pinning strength, and ac amplitude. We also consider the case where a dc drive applied perpendicular to the substrate asymmetry direction generates a net flow of vortices perpendicular to the dc drive, producing a geometric or drift ratchet that arises due to non-Gaussian dynamically generated fluctuations. The drift ratchet is more efficient than the ac driven ratchet and also exhibits a series of reversals for varied parameters. Our results should be general to a wide class of systems undergoing nonequilibrium dynamics on conformal substrates, such as colloidal particles on optical traps.