Controlling Single-Pulse Magnetization Switching through Angular Momentum Reservoir Engineering

TL;DR

This study demonstrates how engineering angular momentum transfer in CoGd bilayers enables control over the speed of single-pulse all-optical helicity-independent magnetization switching, revealing a unified framework for fast and slow reversal mechanisms.

Contribution

It introduces a systematic approach to tuning magnetization reversal dynamics via layer composition and spacer layers, highlighting the role of angular momentum transfer pathways.

Findings

Efficient angular momentum transfer leads to ultrafast Co reversal.

Reducing Gd thickness or adding a Pt spacer slows down switching.

Replacing Gd with heavier rare-earths like Dy or Ho reduces transfer and delays reversal.

Abstract

We report a systematic study of single pulse all optical helicity independent switching in CoGd bilayers, revealing that the magnetization reversal dynamics can be tuned over more than three orders of magnitude. By varying the Gd thickness or inserting a Pt spacer layer between Co and Gd, we control the angular momentum transferred from the rare earth sublattice to the transition metal sublattice. Our results show that when Gd is abundant and strongly coupled to Co, angular momentum is efficiently transferred during Gd demagnetization, leading to ultrafast Co reversal. In contrast, reducing the Gd thickness or introducing a Pt barrier impedes this transfer, resulting in a domain growth mediated reversal on nanosecond and possibly to microsecond timescales as previously observed in CoDy and CoHo alloys. As a result, in rare earth transition metal systems, replacing Gd with heavier rare-earth elements such as Dy or Ho slows down the switching due to a reduced angular momentum transfer towards Co upon demagnetization as demonstrated in CoGdDy alloys. Our findings establish angular momentum availability and transfer pathways as key parameters governing AO HIS dynamics, offering a unified framework for fast and slow magnetization reversal across rare earth transition metal systems.