Micro-structuration effects on local magneto-transport in [Co/Pd]IrMn thin films

TL;DR

This study investigates how micro-structuration and contact geometry influence local magneto-transport signals in exchange-biased [Co/Pd]IrMn thin films, revealing that contact placement significantly affects measurement accuracy.

Contribution

It demonstrates that contact geometry and micro-structuration critically impact local magneto-transport measurements, providing insights for more accurate characterization of thin film magnetic properties.

Findings

Contact placement drastically alters EHE signal shape.

Tilting magnetic field has minimal effect on MT signals.

Deformed signals can be modeled as a mix of EHE and MR.

Abstract

We measured the local magneto-transport (MT) signal with an out-of-plane magnetic field, including magneto-resistance (MR) and Extraordinary Hall effect (EHE), in exchange-biased [Co/Pd]IrMn thin multilayers that are micro-structured with a 100 micron window. We found that when measured locally around the window, the MT signal deviate from the expected behavior. We studied possible causes, including film micro-structuration, electrical contact geometry as well as magnetic field tilt from the normal direction. These MT measurements were carried using the Van-der-Pauw method, with a set a four microscopic contacts directly surrounding the window, and a set of four contacts positioned several millimeters away from the window. We found that tilting the magnetic field direction with respect to the normal does not significantly affect the MT signal, whereas the positioning and geometry of the contacts seem to highly affect the MT signal. When the contacts are directly surrounding the window, the shape of the EHE signal is drastically deformed, suggesting that the electron path is disturbed by the presence of the window and the proximity of the electric contacts. If, on the other hand, the contacts are sufficiently far apart, the MT signal is not significantly affected by the presence of the window. Furthermore, the deformed EHE signal measured on the inner contacts can be modeled as a mix of the EHE and MR signals measured on the outer contacts.