Title :
Material Properties of Si-Ge/Ge Quantum Wells
Author :
Schaevitz, Rebecca K. ; Roth, Jonathan E. ; Ren, Shen ; Fidaner, Onur ; Miller, David A B
Author_Institution :
Electr. Eng. Dept., Stanford Univ., Stanford, CA
Abstract :
Germanium (Ge) and silicon-germanium (Si-Ge) have the potential to integrate optics with Si IC technology. The quantum-confined Stark effect, a strong electroabsorption mechanism often observed in III-V quantum wells (QWs), has been demonstrated in Si-Ge/Ge QWs, allowing optoelectronic modulators in such group IV materials. Here, based on photocurrent electroabsorption experiments on different samples and fitting of the resulting allowed and nominally forbidden transitions, we propose more accurate values for key parameters such as effective masses and band offsets that are required for device design. Tunneling resonance modeling including conduction band nonparabolicity was used to fit the results with good consistency between the experiments and the fitted transitions.
Keywords :
Ge-Si alloys; Stark effect; conduction bands; elemental semiconductors; germanium; photoconductivity; semiconductor quantum wells; SiGe-Si; band offsets; conduction band; effective masses; optoelectronic modulators; photocurrent electroabsorption; quantum wells; quantum-confined Stark effect; tunneling resonance modeling; Conducting materials; Germanium silicon alloys; III-V semiconductor materials; Integrated optics; Material properties; Optical materials; Optical modulation; Photonic integrated circuits; Silicon germanium; Stark effect; Germanium (Ge); optical interconnects; quantum-confined Stark effect (QCSE); silicon (Si);
Journal_Title :
Selected Topics in Quantum Electronics, IEEE Journal of
DOI :
10.1109/JSTQE.2008.918935
