2.8 Direct Gap: Ge/SiGeSn Heterojunctions
In this section, some of the recent developments in heterostructures made of group IV elements and their alloys will be mentioned. The most interesting features of the heterostructures are that direct gap can be obtained in the active material, which is mainly Ge, and that the band alignments are type I. Further, the multilayered structures may be grown on silicon platform.
2.8.1 Structures
The conventional heterostructures combining Ge, Si1−xGex, and Si1−x−yGexCy have the limitations that the active layers are indirect gap in nature, and in addition the Si–Si1−xGex heterostructures mostly show type II band alignment. These heterostructures are not useful as light emitters. SiGeC grown on Si is believed to show type I alignment 10; however, the band gap is still indirect.
The band gap variation in SiGe alloys with incorporation of Sn has been investigated by Soref and coworkers [14, 16], who predicted that the direct band gap may be achieved in SiGeSn ternary alloy for some compositions of Sn.
Recently, two significant achievements have been made in the quest for direct-gap group IV materials. The first is the growth of device-quality Ge1−ySny alloy, in which an indirect-to-direct gap crossover is expected for y 0.2 17. The second is the development of Ge1−x−ySixSny ternary alloy 18, the band gap of which has been theoretically studied by ...
Get Silicon Photonics: Fundamentals and Devices now with the O’Reilly learning platform.
O’Reilly members experience books, live events, courses curated by job role, and more from O’Reilly and nearly 200 top publishers.