Convoluted Magnetoresistance and Magnetic Reversal Processes in Ni-Fe Segmented Cylindrical Nanodots with Tunable Size and Composition for Technological Applications

Due to their unique properties, bi-segmented systems are currently used in several technological applications such as sensing devices, high density magnetic data storage systems, spintronics and microelectromechanical components, among others. In this study, the magnetoresistance and magnetic properties of Ni-Fe bi-segmented cylindrical nanodots in a broad range of diameters and heights are discussed. The power of the First Principles approach, as considered in the density functional theory formulation, is used to study the structural and magnetic relaxation effects, and atomistic simulations, through the Fast Monte Carlo methodology, are employed to explore the magnetoresistance and magnetic behaviors of these systems. By means of the magnetic hysteresis and magnetoresistance signals, convoluted magnetization reversal schemes are discussed. These effects take place depending on the size of the Ni and Fe components as a result of the interplay among exchange interactions and size and shape effects induced by dipolar interactions. Since size has become an experimental controllable parameter, due to the enriched phenomena, the effects discussed in these bi-component systems are useful for the design and production of devices for technological applications with relevance beyond the observed in the more restricted single component systems.

Automated summary

This study discusses the magnetoresistance and magnetic properties of Ni-Fe bi-segmented cylindrical nanodots with different diameters and heights. The structural and magnetic relaxation effects are investigated using the density functional theory approach, and the magnetoresistance and magnetic behaviors are explored through atomistic simulations using the Fast Monte Carlo methodology. The convoluted magnetization reversal schemes are discussed based on the magnetic hysteresis and magnetoresistance signals, which are influenced by the size and shape effects induced by dipolar interactions and the interplay among exchange interactions.