Ultrafast optical measurements of spin-polarized electron dynamics in nanostructured magnetic materials

Mohamad, Haidar Jawad

January 2015

At present, electronic devices depend upon electric charge to transfer and record information. However, such devices are approaching a scaling limit due to Joule heating. Spintronics offers a solution by exploiting the spin rather than the charge of the electron, since the propagation of spin current can in principle occur without dissipation. Immediate applications lie in magnetic random access memory and novel media for hard disk recording. Within this thesis, the Magneto-optical Kerr effect (MOKE) has been used to measure the static and dynamic magnetic properties of a number of different thin film samples that are of interest for spintronic applications. A femtosecond laser has been used to perform time-resolved MOKE (TRMOKE) and time resolved reflectivity (TRR) measurements simultaneously, which probe the spin and charge dynamics respectively. Measurements have been performed upon a continuous thin film of CrO2 that is known to be half-metallic in bulk form, and a series of YIG/Cu/Ni81Fe19 based structures that are expected to exhibit the spin Seebeck effect (SSE). Chemical vapour deposition (CVD) was used to fabricate the continuous CrO2 thin film on a (100)-oriented TiO2 substrate. Precessional magnetisation dynamics were studied by means of the TRMOKE technique. The dependence of the precession frequency and the effective damping parameter upon the static applied magnetic field were investigated. The precession frequency exhibited a minimum at the hard axis saturation field as expected. However precession was also observed for fields greater than the hard axis saturation value, perhaps suggesting the presence of a twisted magnetic state within the film. TRMOKE and TRR measurements were performed upon the YIG/Cu/Ni81Fe19 based structures for different values of the pump fluence and applied magnetic field. For fixed pump fluence and varying applied field, the frequency of precession is well described by a numerical solution of the Landau-Lifshitz equation for the Ni81Fe19 (permalloy, Py) layer. The frequency, amplitude, damping, phase and chirp of the precessional oscillations was extracted from measurements made with a field of 3 kOe applied at 2.8° from the normal to the sample plane, in a configuration designed to maximise any spin transfer torque (STT) generated by the SSE. The oscillation parameters extracted for trilayer samples and a Py reference sample were found to be very similar. Features indicative of STT predicted by simulations were not observed. This suggests that either the YIG/Cu interface was unable to efficiently transmit spin current within the samples studied here, or else that the STT generated by means of the SSE is too small to be of practical use.

530

Photo-magnonics in two-dimensional antidot lattices

Lenk, Benjamin

12 December 2012

No description available.

530 Physik

Physics

Magnonik

magnonische Kristalle

Metamaterial

Lochgitter

TRMOKE

fs-Laser

Pump-Abfrage

Population

Anregung

Bandstruktur

Spinwellen

Magnonen

Blochwellen

lokalisierte Moden

Nickel

CoFeB

magnonics

magnonic crystal

metamaterial

antidot lattice

TRMOKE

fs-laser

pump-probe

population

excitation

band structure

spin wave

magnon

Bloch wave

localized modes

nickel

CoFeB

33.16

33.75

Physics of laser heated ferromagnets: Ultrafast demagnetization and magneto-Seebeck effect / Physik lasergeheizter Ferromagnete: Ultraschnelle Entmagnetisierung und magneto-Seebeck Effekt

Walowski, Jakob

05 March 2000

No description available.

530 Physik

RDE 000

RVC 860

RNL 500

Physics

Femtosekundenspektroskopie

Nickel

TRMOKE

Zeitaufgelöste Reflektivität

ultraschnelle Entmagnetisierung

Spin Kaloritronik

magneto-Seebeck Effekt

Tunnelelement

CoFeB

MgO

femtosecond spectroscopy

nickel

TRMOKE

time-resolved reflectivity

ultrafast demagnetization

spin caloritronics

magneto-Seebeck effect

tunneljunction

CoFeB

MgO

33.75

33.79

33.05

33.07