Title :
Temperature-Stable 980-nm VCSELs for 35-Gb/s Operation at 85 °C With 139-fJ/bit Dissipated Heat
Author :
Hui Li ; Wolf, Philip ; Moser, Philip ; Larisch, Gunter ; Lott, James A. ; Bimberg, Dieter
Author_Institution :
Inst. fur Festkorperphys. und Zentrum fur Nanophotonik, Tech. Univ. Berlin, Berlin, Germany
Abstract :
Energy-efficient oxide-confined 980-nm vertical-cavity surface-emitting lasers (VCSELs) operating at 35 Gb/s at 85 °C with only 139 fJ/bit of dissipated heat are reported. Oxide-aperture-dependent static characteristics and high-speed modulation properties at a high operation temperature of 85 °C are studied in detail. It is demonstrated that oxide-aperture diameters of ~3-4 μm are most suitable for energy-efficient and high bit rate operation at high temperatures. Data transmission experiments for ~3, 3.5, and 4 μm oxide-aperture diameter VCSELs are performed and the results are compared to formulate methods to minimize energy dissipation per bit. To date, our 980-nm VCSELs are the most energy-efficient VCSELs operating at 85 °C at any wavelength.
Keywords :
optical interconnections; optical modulation; surface emitting lasers; thermo-optical devices; bit rate 35 Gbit/s; data transmission experiments; dissipated heat; energy dissipation; energy-efficient VCSEL; energy-efficient operation; energy-efficient oxide-confined vertical-cavity surface-emitting lasers; high bit rate operation; high operation temperature; high-speed modulation properties; oxide-aperture diameter VCSEL; oxide-aperture-dependent static characteristics; temperature 85 degC; temperature-stable VCSEL; wavelength 980 nm; Apertures; Bit rate; Energy efficiency; Modulation; Optical interconnections; Threshold current; Vertical cavity surface emitting lasers; Energy efficiency; high-speed modulation; multimode optical fiber; optical interconnects; vertical-cavity surface-emitting lasers;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2014.2354736
