By injecting spin-polarised
electrons in semiconductor based
microlasers, modulation speeds
can be reached that are far
superior to any conventional
This is a decisive step towards high-speed data transmission, for example for the Internet of tomorrow. Optical data transmission by semiconductor lasers is a basic prerequisite for the globally networked world and today’s information society. The ever increasing degree of networking and the desire to exchange larger amounts of data are the driving force behind the development of ever faster optical data transmission systems. The maximum speed of conventional semiconductor lasers has long been a limiting factor - typical modulation frequencies are currently at levels well below 50 GHz.
By using spin lasers, Bochum’s researchers were able to overcome the previous limits for the modulation speed. Whereas in conventional lasers, the spin of the electrons injected is entirely arbitrary, in spin lasers, only electrons with a previously determined spin state are used. By injecting these spin-polarised electrons, the laser is forced to work simultaneously on two laser modes with different frequencies.
“This frequency difference can easily be tuned using the so-called birefringence in the resonator, for example by simply bending the micro laser” said Doctor Nils Gerhardt. By coupling the two laser modes in the micro resonator, oscillation with a new frequency occurs, which can theoretically reach well over 100 GHz. The researchers around Gerhardt obtained their results in the collaborative research centre 491 of the Universities of Bochum and Duisburg-Essen.
COMPAMED.de; Source: Ruhr Universität Bochum