Litcius/Paper detail

Materials Engineering Enabled by Time-Resolved Magneto-Optical Kerr Effect for Spintronic Applications

Dingbin Huang, Dustin M. Lattery, Xiaojia Wang

2020ACS Applied Electronic Materials26 citationsDOI

Abstract

As an updated version of the ultrafast pump–probe laser technique, the time-resolved magneto-optical Kerr effect (TR-MOKE) methodology enables the detection of magnetization dynamics with superb temporal (sub-picosecond) and spatial (diffraction-limited beam spot) resolutions. It is a powerful tool to characterize material properties and to reveal the rich physics of magnetization dynamics in magnetic thin films, which serve as the essential building blocks for spintronic and magnetic recording devices. In this spotlight article, we will highlight the recent advances in the development of TR-MOKE metrology and its applications for capturing the magnetization dynamics in technologically important spintronic materials. We cover several representative examples based on research activities carried out at the University of Minnesota (UMN), including studies of Gilbert damping, spin-strain coupling, and interlayer exchange coupling of perpendicular magnetic materials. A brief discussion will be also presented, which highlights several other emerging research topics that are potentially enabled by this metrology to form a more comprehensive picture of its applications for emerging materials and technologies.

Topics & Concepts

SpintronicsMagnetization dynamicsKerr effectPicosecondMetrologyUltrashort pulseMagnetizationMaterials scienceMagneto-optic Kerr effectCoupling (piping)NanotechnologyEngineering physicsCondensed matter physicsPhysicsOpticsLaserFerromagnetismMagnetic fieldNonlinear systemQuantum mechanicsMetallurgyMagnetic properties of thin filmsMagneto-Optical Properties and ApplicationsSemiconductor Quantum Structures and Devices