Abstract: A semiconductor device such as a photodetector has a substrate having an active region layer containing an active region of the device. A dielectric layer is disposed on the active region layer, and a metal active region contact is disposed in the dielectric layer above the active region and electrically contacting the active region. A metal electrostatic discharge (ESD)protection structure is disposed in the dielectric layer around the active region contact, wherein the ESD protection structure electrically contacts the active region layer of the substrate to provide an ESD discharge path for charge on the surface of the dielectric layer.

Abstract: A semiconductor device such as a photodetector has a substrate having an active region layer containing an active region of the device. A dielectric layer is disposed on the active region layer, and a metal active region contact is disposed in the dielectric layer above the active region and electrically contacting the active region. A metal electrostatic discharge (ESD) protection structure is disposed in the dielectric layer around the active region contact, wherein the ESD protection structure electrically contacts the active region layer of the substrate to provide an ESD discharge path for charge on the surface of the dielectric layer.

Abstract: A semiconductor device such as a photodetector has a substrate having an active region layer containing an active region of the device. A dielectric layer is disposed on the active region layer, and a metal active region contact is disposed in the dielectric layer above the active region and electrically contacting the active region. A metal electrostatic discharge (ESD) protection structure is disposed in the dielectric layer around the active region contact, wherein the ESD protection structure electrically contacts the active region layer of the substrate to provide an ESD discharge path for charge on the surface of the dielectric layer.

Abstract: Prior to packaging, semiconductor lasers are purged by being subjected first to high temperature and high current simultaneously so as to suppress stimulated emission and stress the shunt paths which allow leakage current to flow around the active region. A prudent, but nonessential, second step is to lower the temperature and/or current so that the lasers emit stimulated emission (preferably strongly, near the peak output power), thereby stressing the active region. Lasers subjected to such a purge exhibit stabilized degradation rates in short times (of the order of a few hours) and provide a robust population which meets the performance criteria of long lifetime systems.

Abstract: Current confinement in semiconductor devices by means of buried high resistivity zones is described. For example, in a stripe geometry, semiconductor, junction laser the laterally separate, high resistivity zones, which confine current flow in a narrow channel between the upper and lower electrical contacts, are buried below the upper contact. This configuration permits current to flow from the upper contact into the body of the semiconductor over greatly increased area before it enters the channel. The current density at the interface between the upper contact and the semiconductor body is thereby reduced, making the quality of that interface less important. Several processes which employ proton bombardment for fabricating the laser are also described: (1) in one the normal sequence of Zn diffusion and proton bombardment is reversed, and (2) in the other the profiles of Zn doping and proton damage are suitably tailored.