Title :
Simple Electroabsorption Calculator for Designing 1310 nm and 1550 nm Modulators Using Germanium Quantum Wells
Author :
Schaevitz, Rebecca K. ; Edwards, Elizabeth H. ; Roth, Jonathan E. ; Fei, Edward T. ; Rong, Yiwen ; Wahl, Pierre ; Kamins, Theodore I. ; Harris, James S. ; Miller, David A B
Author_Institution :
Dept. of Electr. Eng., Stanford Univ., Stanford, CA, USA
Abstract :
With germanium showing significant promise in the design of electroabsorption modulators for full complementary metal oxide semiconductor integration, we present a simple electroabsorption calculator for Ge/SiGe quantum wells. To simulate the quantum-confined Stark effect electroabsorption profile, this simple quantum well electroabsorption calculator (SQWEAC) uses the tunneling resonance method, 2-D Sommerfeld enhancement, the variational method and an indirect absorption model. SQWEAC simulations are compared with experimental data to validate the model before presenting optoelectronic modulator designs for the important communication bands of 1310 nm and 1550 nm. These designs predict operation with very low energy per bit ( <; 30×fJ/bit).
Keywords :
Ge-Si alloys; electro-optical modulation; electroabsorption; elemental semiconductors; germanium; optical design techniques; quantum confined Stark effect; semiconductor quantum wells; tunnelling; variational techniques; 2D Sommerfeld enhancement; Ge-SiGe; communication bands; electroabsorption modulators; full complementary metal oxide semiconductor integration; germanium quantum wells; optoelectronic modulator designs; quantum well electroabsorption calculator; quantum-confined Stark effect electroabsorption; tunneling resonance method; variational method; wavelength 1310 nm; wavelength 1550 nm; Absorption; Excitons; Modulation; Silicon; Tunneling; Germanium; modulators; optical interconnects; optoelectronic; quantum wells; quantum-confined Stark effect; silicon;
Journal_Title :
Quantum Electronics, IEEE Journal of
DOI :
10.1109/JQE.2011.2170961
