Understanding the metamagnetic transition and magnetic behavior of Ni48Co6Mn26Al20 polycrystalline ribbons

TL;DR

This study investigates the magnetic properties of Ni48Co6Mn26Al20 polycrystalline ribbons, revealing a complex interplay of ferromagnetic and antiferromagnetic interactions leading to a metamagnetic transition and magnetic disorder at low temperatures.

Contribution

It provides a detailed analysis of the magnetic behavior and phase transitions in Ni48Co6Mn26Al20 ribbons, introducing a cluster model based on Ne9el theory to explain ferromagnetic and antiferromagnetic cluster formation.

Findings

Ne9el temperature around 170 K

Ferro to para-like transition at approximately 200 K

Presence of competing magnetic exchange interactions

Abstract

In this work we demonstrate that the polycrystalline ribbons of (Ni48Co6)Mn26Al20 with B2 structure at room temperature show a magnetic behavior with competing magnetic exchange interactions leading to frozen disorders at low temperatures. It is established that by considering the presence of both antiferromagnetic and ferromagnetic sublattices, we can explain the observed magnetic behavior including the metamagnetic transition observed in these samples. From the Arrott plots, the N\'eel temperature of (Ni48Co6)Mn26Al20 is deduced to be ~170 K and the broad ferro to para like magnetic phase transition is observed at ~ 200 K. Based on N\'eel theory, a cluster model is used to explain the presence of ferromagnetic and anti-ferromagnetic clusters in the studied ribbons. Formation of ferromagnetic clusters can be understood in terms of positive exchange interactions among the Mn atoms that are neighboring to Co atoms which are located on the Ni sites.