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Key technology applications like magnetoresistive sensors or the Magnetic Random Access Memory (MRAM) require reproducible magnetic switching mechanisms. i.e. predefined remanent states. At the same time advanced magnetic recording schemes push the magnetic switching time into the gyromagnetic regime. Objects of study in this study are antiparallel pinned synthetic spin valves as they are extensively used as read heads in today's magnetic storage devices. Results are reported of element specific Time Resolved Photo_Emission Electron Microscopy (TR_PEEM) to image the magnetization dynamics of…mehr

Produktbeschreibung
Key technology applications like magnetoresistive sensors or the Magnetic Random Access Memory (MRAM) require reproducible magnetic switching mechanisms. i.e. predefined remanent states. At the same time advanced magnetic recording schemes push the magnetic switching time into the gyromagnetic regime. Objects of study in this study are antiparallel pinned synthetic spin valves as they are extensively used as read heads in today's magnetic storage devices. Results are reported of element specific Time Resolved Photo_Emission Electron Microscopy (TR_PEEM) to image the magnetization dynamics of the free layer alone via X_ ray Circular Dichroism (XMCD). The observation of magnetic switching processes in the gigahertz range became possible due to the joined effort of producing ultra_short X_ray pulses at BESSY II and optimizing the wave guide design of the samples for high frequency electromagnetic excitation. It could be shown that the magnetization dynamics of the free layer of a GMR spin valve stack deviates significantly from a simple phase coherent rotation.
Autorenporträt
Dr. Frederik Wegelin, geb. 1973, studierte in an der Johannes-Gutenberg Universität in Mainz Physik und forschte während Diplom- und Doktorarbeit in Entwicklungsprojekten mit IBM Speichersysteme GmbH bzw. Sensitec GmbH an den Grundlagen der modernen Magnetspeichertechnologie.