Qi, MengO'Brien, William A.Stephenson, Chad A.Patel, VictorCao, NingThibeault, Brian J.Schowalter, MarcoRosenauer, AndreasProtasenko, VladimirXing, Huili GraceWistey, Mark A.2019-04-092019-04-092017-03-26Qi, M., O’Brien, W. A., Stephenson, C. A., Patel, V., Cao, N., Thibeault, B. J., Schowalter, M., Rosenauer, A., Protasenko, V., Xing, H. G. & Wistey, M. A. (2017). Extended Defect Propagation in Highly Tensile-Strained Ge Waveguides. Crystals, 7, 157.https://hdl.handle.net/10877/7969Tensile-strained Ge is a possible laser material for Si integrated circuits, but reports of lasers using tensile Ge show high threshold current densities and short lifetimes. To study the origins of these shortcomings, Ge ridge waveguides with tensile strain in three dimensions were fabricated using compressive silicon nitride (SiNx) films with up to 2 GPa stress as stress liners. A Raman peak shift of up to 11 cm−1 was observed, corresponding to 3.6% hydrostatic tensile strain for waveguides with a triangular cross-section. Real time degradation in tensile-strained Ge was observed and studied under transmission electron microscopy (TEM). A network of defects, resembling dark line defects, was observed to form and propagate with a speed and density strongly correlated with the local strain extracted from both modeled and measured strain profiles. This degradation suggests highly tensile-strained Ge lasers are likely to have significantly shorter lifetime than similar GaAs or InGaAs quantum well lasers.Text10 pages1 file (.pdf)enstrained germaniumstress linertensile straindirect bandgapdark line defectsoptical waveguidestabilitysilicon photonicsPhysicsArticle© 2017 The Authors.https://doi.org/10.3390/cryst7060157This work is licensed under a Creative Commons Attribution 4.0 International License.