Fast manipulation of a magnet by light

 

Angular momentum transfer from a spin-polarized electrical current to magnetization in a ferromagnet is the so called spin-transfer-torque phenomenon. It allows, for example, to write information in the latest generation of magnetic random access memories whose development is expected to result in the construction of instant on-and-off computers. The timescales for exciting magnetization by the current induced spin-transfer-torque are nanoseconds. Physicists from the joint Laboratory of Opto-Spintronics observed an optical variant of the phenomenon, the so called optical spin-transfer-torque, in which magnetization is excited in a magnetic semiconductor by polarized photo-carriers at timescales which are several orders of magnitude shorter. The material for the experiment was a GaAs semiconductor doped with manganese, which was prepared by atomic layer-by-layer growth in the Institute of Physics of the Academy of Sciences. Femtosecond pump-and-probe technique for optically exciting and detecting magnetization dynamics was employed by scientists at the Faculty of Mathematics and Physics of the Charles University.

 

„Our work combines the photo-effect, a phenomenon which is at the very heart of semiconductor opto-electronics, with the spin-transfer-torque which is the key phenomenon for spintronics and magnetic memories. We have, therefore, built a new bridge between these two modern fields of research in microelectronics“, say Petr Němec and Tomáš Jungwirth from the join Laboratory of Opto-Spintronics.

 

Figure shows the physical principle of  the optical spin-transfer-torque and the experimental observation of the optical excitation of the ferromagnetic semiconductor by short, circularly-polarized laser pulses allowed by the new phenomenon.

 

For detail information contact Tomáš Jungwirth from the Institute of Physics AVCR, v.v.i., Cukrovarnická 10, 162 53 Praha 6, e-mail: jungw@fzu.cz