Abstract

1.55-/spl mu/m-wavelength distributed reflector (DR) lasers with low threshold and high efficiency were realized which consisted of a distributed feedback (DFB) grating and high-reflection distributed Bragg reflector (DBR) sections integrated by utilizing the lateral quantum confinement effect in a quantum-wire structure. In order to realize a high-performance DR laser, the high-reflection DBR structure was investigated theoretically and experimentally and could be fabricated with a reflectivity of over 90%, taking into consideration the absorption in the active layers. The highest differential quantum efficiency of 36% from the front facet was obtained for the 4.4-/spl mu/m stripe width and 300-/spl mu/m DFB section length under room temperature (RT) and continuous-wave (CW) conditions. Moreover, the lowest threshold current of 1.5 mA was obtained for the 3.4-/spl mu/m stripe width and 150-/spl mu/m DFB length.