Abstract
The binary alloy germanium tin has already been presented as a direct group IV semiconductor at high tin concentrations and specific strain. Therefore, it offers a promising approach for the monolithic integrated light source towards the optical on-chip communication on silicon. However, the main challenge faced by many researchers is the achievement of high tin concentrations and good crystal quality. The key issues are the lattice mismatch to silicon and germanium, as well as the limited solid solubility of tin in germanium of less than 1%. Therefore, this paper presents a systematic investigation of the epitaxial growth conditions of germanium tin with tin concentrations up to 17%. For this, we performed two growth experiments utilizing molecular beam epitaxy. In one experiment, we varied the growth temperature for the epitaxy of germanium tin with 8% tin to investigate the inter-growth temperature stability. In the second experiment, we focused on the strain-relaxation of germanium tin, depending on different tin concentrations and doping types. The results of subsequent material analysis with x-ray diffraction and scanning electron microscopy allow us to narrow the epitaxial window of germanium tin. Furthermore, we present a possible explanation for the unique relaxation mechanism of germanium tin, which is significantly different from the well-known relaxation mechanism of silicon germanium.
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M. Oehme, J. Werner, M. Jutzi, G. Wöhl, E. Kasper, and M. Berroth, Thin Solid Films 508, 393 (2006).
M. Oehme, J. Werner, M. Kaschel, O. Kirfel, and E. Kasper, Thin Solid Films 517, 137 (2008).
Y.-H. Kuo, Y.K. Lee, Y. Ge, S. Ren, J.E. Roth, T.I. Kamins, D.A.B. Miller, and J.S. Harris, IEEE J. Sel. Top. Quantum Electron. 12, 1503 (2006).
M. Oehme, K. Kostecki, M. Schmid, M. Kaschel, M. Gollhofer, K. Ye, D. Widmann, R. Koerner, S. Bechler, E. Kasper, and J. Schulze, Appl. Phys. Lett. 104, 161115 (2014).
R. Koerner, D. Schwaiz, I.A. Fischer, L. Augel, S. Bechler, L. Haenel, M. Kern, M. Oehme, E. Rolseth, B. Schwartz, D. Weisshaupt, W. Zhang, and J. Schulze, in 2016 IEEE International Electron Devices Meeting (IEDM) (2016), pp. 22.5.1–22.5.4.
S. Wirths, R. Geiger, N. von den Driesch, G. Mussler, T. Stoica, S. Mantl, Z. Ikonic, M. Luysberg, S. Chiussi, J.M. Hartmann, H. Sigg, J. Faist, D. Buca, and D. Grützmacher, Nat. Photonics 9, 88 (2015).
L. Jiang, J.D. Gallagher, C.L. Senaratne, T. Aoki, J. Mathews, J. Kouvetakis, and J. Menéndez, Semicond. Sci. Technol. 29, 115028 (2014).
R.W. Olesinski and G.J. Abbaschian, Bull. Alloy Phase Diagr. 5, 265 (1984).
R.W. Olesinski and G.J. Abbaschian, Bull. Alloy Phase Diagr. 5, 273 (1984).
E. Kasper, J. Werner, M. Oehme, S. Escoubas, N. Burle, and J. Schulze, Thin Solid Films 520, 3195 (2012).
H. Li, C. Chang, T.P. Chen, H.H. Cheng, Z.W. Shi, and H. Chen, Appl. Phys. Lett. 105, 151906 (2014).
M. Oehme, K. Kostecki, M. Schmid, F. Oliveira, E. Kasper, and J. Schulze, Thin Solid Films 557, 169 (2014).
B. Predel, in Ac-Ag… Au-Zr, edited by B. Predel (Springer, Berlin, 2006), pp. 1–23.
E. Kasper, M. Bauer, and M. Oehme, Thin Solid Films 321, 148 (1998).
L. Kormoš, M. Kratzer, K. Kostecki, M. Oehme, T. Šikola, E. Kasper, J. Schulze, and C. Teichert, Surf. Interface Anal. 49, 297 (2017).
R. Beeler, R. Roucka, A.V.G. Chizmeshya, J. Kouvetakis, and J. Menéndez, Phys. Rev. B 84, 035204 (2011). https://doi.org/10.1103/PhysRevB.84.035204.
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Schwarz, D., Funk, H.S., Oehme, M. et al. Alloy Stability of Ge1−xSnx with Sn Concentrations up to 17% Utilizing Low-Temperature Molecular Beam Epitaxy. J. Electron. Mater. 49, 5154–5160 (2020). https://doi.org/10.1007/s11664-020-08188-6
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DOI: https://doi.org/10.1007/s11664-020-08188-6