Generation of Ultrafast Magnetic Steps for Coherent Control

TL;DR

This paper presents a novel method to generate ultrafast magnetic field steps using supercurrent quench in superconductors, enabling coherent control of magnetization with potential for advanced data storage and phase transition studies.

Contribution

A new technique for creating ultrafast magnetic field steps with picosecond risetimes using supercurrent quench in superconductors, advancing magnetic control capabilities.

Findings

Achieved magnetic field steps with millitesla amplitude and picosecond risetimes.

Demonstrated coherent rotation of magnetization in a ferrimagnet.

Potential for larger and faster magnetic steps with device improvements.

Abstract

A long-standing challenge in ultrafast magnetism and in functional materials research in general, has been the generation of a universal, ultrafast stimulus able to switch between stable magnetic states. Solving it would open up many new opportunities for fundamental studies, with potential impact on future data storage technologies. Ideally, step-like magnetic field transients with infinitely fast rise time would serve this purpose. Here, we develop a new approach to generate ultrafast magnetic field steps, based on an ultrafast quench of supercurrents in a superconductor. Magnetic field steps with millitesla amplitude, picosecond risetimes and slew rates approaching 1 GT/s are achieved. We test the potential of this technique by coherently rotating the magnetization in a ferrimagnet. With suitable improvements in the geometry of the device, these magnetic steps can be made both larger and faster, leading to new applications that range from quenches across phase transitions to complete switching of magnetic order parameters.