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Ultrafast Laser Pulses Meet Magnetic Materials in New Research

Feb 20, 2017     Email"> PrintText Size

 

A time-resolved magneto-optical Kerr effect measurement system. Credit: ©Science China Press 

Researchers have studied ultrafast non-equilibrium magnetization in correlated spin systems in recent years. At both fundamental and application levels, ultrafast laser pulse excitation and dynamics measurement provide an effective path to fast optical detection, as well as control of magnetic order. Studies have been conducted with magnetic media measuring the time-resolved magneto-optical Kerr effect (TR-MOKE), ultrafast magnetic relaxation phenomenon such as ultrafast demagnetization and uniform precession. The optically excited magnetization precession in magnetic media exhibits the temporal response of magnetization when the effective magnetic field is instantaneously changed by ultrafast laser pulse excitation and provides information about the spin dynamics microscopically.

Recently, research has focused on the BiFeO3 (BFO) and Sr-doped LaMnO3 heterostructure for a series of novel physical properties that originate from the antiferromagnetic (AFM) and ferromagnetic (FM) exchange interaction across the heterointerface. In an article recently published in SCIENCE CHINA Physics, Mechanics & Astronomy, researchers at the Institute of Physics, Chinese Academy of Sciences, reported their investigation on the ultrafast laser-excited magnetization dynamics of ferromagnetic (FM) La0.67Sr0.33MnO3 (LSMO) thin films with epitaxial grown BiFeO3 (BFO) coating layers.

These researchers fabricated the BFO/LSMO heterostructure using the laser molecular beam epitaxy system. As designed, 10-nm-thick LSMO thin films were deposited on (001) SrTiO3 (STO) single-crystal substrates, and three- or 20-nm-thick BFO films were coated onto the LSMO films. X-ray diffraction was carried out for structural characterization. With the ultrafast time-resolved magneto-optical Kerr effect (TR-MOKE) measurement system they built, the researchers measured the temporal response of the samples they prepared within the time scale of ~500 ps using a pump-probe technique.

 

Transient Kerr rotation signals of the uncoated LSMO film and the LSMO films coated with 3- and 20-nm-thick BFO layers under external magnetic fields of 0.2 T (a), 0.4 T (b), and 0.6 T (c). The Fourier transforms of the signals shown in (a), (b), and (c) for external magnetic fields of 0.2 T (d), 0.4 T (e), and 0.6 T (f), respectively. Credit: ©Science China Press 

Two distinct types of oscillations were launched after the pump pulse excited the sample. The high-frequency oscillation at ~103 GHz was independent of the external magnetic field, which was ascribed to the coherent acoustic phonons generated in the STO substrates by the pump-pulse irradiation. The other oscillation mode occurred at a lower frequency (10-30 GHz), exhibiting a positive dependence on the external magnetic field. This relation confirmed the oscillation behavior to be the optically triggered magnetization precession, which has been observed in magnetic media in previous ultrafast TR-MOKE measurements.

Intriguingly, by comparing the optically excited precession behavior of the samples under the same external magnetic fields, the oscillation period of the precession appeared to be expanded for the BFO-coated LSMO films, and the sample coated with 20-nm-thick BFO exhibited a longer oscillation period than that coated with 3-nm-thick BFO. Fourier transforms show distinct shifts of the precession frequency peak position in each case for the same external magnetic field, thus confirming the frequency modulation of the magnetization precession.

The researchers analyzed the effective magnetic field in the LSMO film and attributed the reduction of the precession frequency to the suppression of the anisotropy by BFO coating layers. Moreover, they suppose such behavior was induced by the exchange interaction across the BFO/LSMO interface.

"Investigating the optically excited magnetization precession in magnetic oxides may shed light on potential application in spintronics devices," wrote the researchers. "Our findings may provide an effective approach for controlling the spin behavior in magnetic oxide films through structural design." (phys.org)
 

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(Editor: ZHANG Nannan)

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JIN KuiJuan

Institute of Physics

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