Title :
Plasma-induced quantum well intermixing for monolithic photonic integration
Author :
Djie, Hery Susanto ; Mei, Ting
Author_Institution :
Sch. of Electr. & Electron. Eng., Nanyang Technol. Univ., Singapore
Abstract :
Plasma-induced quantum well intermixing (QWI) has been developed for tuning the bandgap of III-V compound semiconductor materials using an inductively coupled plasma system at the postgrowth level. In this paper, we present the capability of the technique for a high-density photonic integration process, which offers three aspects of investigation: 1) universality to a wide range of III-V compound material systems covering the wavelength range from 700 to 1600 nm; 2) spatial resolution of the process; and 3) single-step multiple bandgap creation. To verify the monolithic integration capability, a simple photonic integrated chip has been fabricated using Ar plasma-induced QWI in the form of a two-section extended cavity laser diode, where an active laser is integrated with an intermixed low-loss waveguide.
Keywords :
III-V semiconductors; energy gap; integrated optics; integrated optoelectronics; laser cavity resonators; monolithic integrated circuits; optical fabrication; optical losses; optical tuning; optical waveguides; plasma materials processing; quantum well lasers; semiconductor quantum wells; 700 to 1600 nm; Ar plasma-induced QWI; III-V semiconductor materials; active laser; bandgap tuning; chip fabrication; compound semiconductor materials; extended cavity laser diode; inductively-coupled plasma system; intermixed low-loss waveguide; monolithic integration; multiple bandgap creation; photonic integrated chip; photonic integration; plasma-induced intermixing; postgrowth level; quantum well intermixing; single-step bandgap creation; spatial resolution; two-section laser diode; Argon; III-V semiconductor materials; Laser tuning; Monolithic integrated circuits; Optical materials; Photonic band gap; Plasma materials processing; Plasma waves; Semiconductor materials; Spatial resolution; Inductively coupled plasma (ICP); photonic integrated circuits (PICs); quantum well; quantum well intermixing (QWI);
Journal_Title :
Selected Topics in Quantum Electronics, IEEE Journal of
DOI :
10.1109/JSTQE.2005.845611
