Atomistic investigation of the temperature and size dependence of the energy barrier of CoFeB/MgO nanodots

TL;DR

This study uses atomistic spin modeling to analyze how size, temperature, and external fields influence the energy barrier in CoFeB/MgO nanodots, revealing complex transition behaviors crucial for MRAM device stability.

Contribution

It provides the first detailed atomistic simulation of energy barriers in CoFeB/MgO nanodots, highlighting the transition from coherent to domain wall reversal processes.

Findings

Energy barrier behavior varies with size and temperature.

Transition from coherent to domain wall reversal identified.

Simulation results agree with experimental data.

Abstract

The balance between low power consumption and high efficiency in memory devices is a major limiting factor in the development of new technologies. Magnetic random access memories (MRAM) based on CoFeB/MgO magnetic tunnel junctions (MTJs) have been proposed as candidates to replace the current technology due to their non-volatility, high thermal stability and efficient operational performance. Understanding the size and temperature dependence of the energy barrier and the nature of the transition mechanism across the barrier between stable configurations is a key issue in the development of MRAM. Here we use an atomistic spin model to study the energy barrier to reversal in CoFeB/MgO nanodots to determine the effects of size, temperature and external field. We find that for practical device sizes in the 10-50 nm range the energy barrier has a complex behaviour characteristic of a transition from a coherent to domain wall driven reversal process. Such a transition region is not accessible to simple analytical estimates of the energy barrier preventing a unique theoretical calculation of the thermal stability. The atomistic simulations of the energy barrier give good agreement with experimental measurements for similar systems which are at the state of the art and can provide guidance to experiments identifying suitable materials and MTJ stacks with the desired thermal stability.