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Nano Focus: Germanium lasers may close Moore’s Gap

Published online by Cambridge University Press:  12 November 2012

Abstract

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Copyright © Materials Research Society 2012

An international team of researchers has investigated the mechanisms necessary for enabling germanium to emit laser light. As a laser material, germanium together with silicon could form the basis for innovative computer chips in which information would be transferred partially in the form of light. This technology would revolutionize data streaming within chips and give a boost to the performance of electronics. Hans Sigg of the Paul Scherrer Institute (PSI) and Jérôme Faist of ETH Zurich in Switzerland, Giovanni Isella of Politecnico di Milano in Italy, and their colleagues have demonstrated that germanium must be put under strain by an external force in order to turn it into a laser material.

While much progress has been made to increase the number of transistors in computer chips, the overall performance of processors has not been able to follow Moore’s law for the past decade, and specialists are now talking about “Moore’s Gap.” The reason for this is that modern chips have more cores—individual processors—that can only relatively slowly communicate with each other using current technology.

“Actually, we do know a way in which this gap can be closed. The key concept is ‘optical data transfer between the different cores on the chip,” says Sigg. “This means partially transferring information inside a chip with the aid of laser pulses, which would significantly speed up the information exchange.” In order to do this, tiny lasers are needed that can be built into chips to send out light pulses.

As reported in the August 3 issue of Physical Review Letters (DOI: 10.1103/PhysRevLett.109.05740; 057402), the researchers investigated those properties of germanium that are important for the generation of laser light, and compared them with those of currently available laser materials. Specifically, they quantified optical gain as a function of carrier density, strain, and doping, and highlighted the role of valence intraband absorption in limiting optical amplification for lasing.

“Our results are, on the one hand, encouraging, because germanium behaves similarly to traditional laser materials, and therefore the possibility of it emitting light cannot be excluded,” says Sigg, “but with the limitation that the balance between amplification and loss is still so unfavorable in the germanium layers investigated so far that the material does not yet fulfill the condition for emitting laser light.” But it has been demonstrated that this condition can be more closely approached the more the germanium is put under strain using an external force.