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Growth of GaAs on (100) Ge and Vicinal Ge Surface by Migration Enhanced Epitaxy

Published online by Cambridge University Press:  01 February 2011

Hendrix Tanoto ,
Soon Fatt Yoon ,
Wan Khai Loke ,
Eugene A. Fitzgerald ,
Carl Dohrman ,
Balasubramanian Narayanan  and
Chih Hang Tung
Hendrix Tanoto
Affiliation:
hendrix@pmail.ntu.edu.sg, Nanyang Technological University, School of Electrical & Electronic Engineering, Clean Room S2-B2c-20, Nanyang Avenue, Singapore, Singapore, 689798, Singapore
Soon Fatt Yoon
Affiliation:
esfyoon@ntu.edu.sg, Nanyang Technological University, School of Electrical & Electronic Engineering, Singapore
Wan Khai Loke
Affiliation:
ewkloke@ntu.edu.sg, Nanyang Technological University, School of Electrical & Electronic Engineering, Singapore
Eugene A. Fitzgerald
Affiliation:
eafitz@mit.edu, Massachusetts Institute of Technology, Department of Materials Science & Engineering, United States
Carl Dohrman
Affiliation:
cdohrman@mit.edu, Massachusetts Institute of Technology, Department of Materials Science & Engineering, United States
Balasubramanian Narayanan
Affiliation:
nara@ime.a-star.edu.sg, Institute of Microelectronics, Singapore
Chih Hang Tung
Affiliation:
chihhang@ime.a-star.edu.sg, Institute of Microelectronics, Singapore
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Abstract

In this paper, we present GaAs/Ge heteroepitaxy grown by RIBER32 solid-source Molecular Beam Epitaxy (SSMBE) with initial GaAs nucleation by migration-enhanced epitaxy (MEE) technique. We look at the influence of substrate temperature during the MEE and the influence of Ge surface orientation to the quality of the GaAs layer. Three samples were grown for this study; the first two samples, sample A and B, have surface orientation of (100) 6° offcut towards (111) plane. This surface orientation was chosen as to achieve double-atomic steps surface that is crucial to suppress anti-phase domain (APD) formation. These samples were then subjected to different temperature during the MEE process, 450°C for sample A and 250°C for sample B. The third sample, sample C, has the same MEE substrate temperature as sample A, which is 450°C but with nominal (100) surface orientation. The growth conditions and structure of the layers after the MEE process were kept constant across the three samples.

We examine the structures and the optical quality of the samples by cross-sectional Transmission Electron Microscope (XTEM) and 5K photoluminescence (PL). Analyzing the XTEM images of sample A and B, it is found that the APD still appear in sample A while it is suppressed totally in sample B. It is also observed from sample A XTEM image that two APDs propagating with 45° and 135° angle, as measured from the GaAs/Ge interface, could meet with each other at certain layer thickness leading to self-annihilation. However, some of the self-annihilations took place only after the APDs propagated hundreds of nanometers in the GaAs layer, producing large undulation in the layer. As for sample B, we believe that the APD suppression is mainly due to the much lower nucleation temperature. At such low temperature, As dimers are adsorbed onto the substrate surface more readily with negligible re-evaporation. This ensures complete As coverage on the double-atomic steps Ge surface and minimize As vacancies that may act as defect initiation centers. Furthermore, the low substrate temperature shortens the migration distance of Ga adatoms, minimizing their adsorption into the kinks and step edges, resulting in two-dimensional growth mode instead of step-flow growth mode.

Meanwhile, XTEM image of sample C shows APDs that propagated almost perpendicularly to the GaAs/Ge interface, making it unlikely for the self-annihilation mechanism to take event. It is understood that the direction of propagation of the APD relies on the atomic steps reconstruction of the Ge starting surface. In the case of single atomic-step surface, the APDs propagate almost perpendicularly to the interface. Finally, the 5K PL spectra of the embedded InGaAs single quantum-well in all the samples clearly demonstrate that the best optical quality comes from sample B; which we believe mainly because of the total suppression of APD, leading to much improved layer quality.

Keywords

molecular beam epitaxy (MBE)transmission electron microscopy (TEM)dislocations
Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 891: Symposium EE – Progress in Semiconductor Materials V – Novel Materials and Electronics and Optoelectronic Applications , 2005 , 0891-EE03-17
Copyright
Copyright © Materials Research Society 2006

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References

REFERENCES

1. Tamura, M., Palmer, J., Yodo, T., and Saitoh, T., Proc. of the SPIE - The Int. Soc. for Opt. Eng. 2400, 128 (1995).Google Scholar
2. Lucas, N., Zabel, H., Morkoc, H., and Unlu, H., App. Phys. Lett. 52, 2117 (1988).10.1063/1.99553Google Scholar
3. Yang, V. K., Groenert, M. E., Taraschi, G., Leitz, C. W., Pitera, A. J., Currie, M. T., Cheng, Z., Fitzgerald, E. A., J. of Mat. Science: Mat. in Elec. 13 (7), 377 (2002).Google Scholar
4. Kroemer, H., J. Crys. Growth 81, 193 (1987).10.1016/0022-0248(87)90391-5Google Scholar
5. Horikoshi, Y., Semicon. Sci. Technol. 8, 1032 (1993).10.1088/0268-1242/8/6/010Google Scholar
6. Sieg, R. M., Ringel, S. A., Ting, S. M., Fitzgerald, E. A., and Sacks, R. N., J. Elec. Mat. 27 (7), 900 (1998).Google Scholar
7. Li, W., Laaksonen, S., Haapamaa, J., and Pessa, M., J. Crys. Growth 227, 104 (2001).10.1016/S0022-0248(01)00641-8Google Scholar
8. Cho, N. H., DeCooman, B. C., Carter, C. B., Fischer, R., and Wagner, D. K., Appl. Phys. Lett. 47, 879 (1985).10.1063/1.95963Google Scholar
9. Fischer, R.. Neuman, D., Zabel, H., and Morkoç, H., Appl. Phys. Lett. 48 (18), 1223 (1986).Google Scholar
10. Ueda, O., Soga, T., Jimbo, T., and Umeno, M., Appl. Phys. Lett. 55 (5), 445 (1989).10.1063/1.101870Google Scholar
11. Chen, G. S., Jaw, D. H., and Stringfellow, G. B., Appl. Phys. Lett. 57, 2475 (1990).10.1063/1.103834Google Scholar