Abstract: A photodetector is integrated on a single semiconductor chip with bipolar transistors including a high speed poly-emitter vertical NPN transistor. The photodetector includes a silicon nitride layer serving as an anti-reflective film. The silicon nitride layer and oxide layers on opposite sides thereof insulate edges of a polysilicon emitter from the underlying transistor regions, minimizing the parasitic capacitance between the NPN transistor's emitter and achieving a high frequency response. The method of manufacture is compatible with existing BiCMOS process technology, the silicon nitride layer of the anti-reflective film being formed over the photodetector as well as regions of the chip that include the vertical NPN transistor and other circuit elements.

Abstract: Fast and efficient photodiodes with different structures are fabricated using CMOS process technology by adapting transistor structures to form the diode structures. The anode regions of the photodiodes correspond to either PLDD regions of PMOS transistors or P-wells of NMOS transistors to provide two different photodiode structures with different anode region depths and thus different drift region thicknesses. An antireflective film used on the silicon surface of the photodiodes is employed as a silicide-blocking mask at other locations of the device.

Abstract: Fast and efficient photodiodes with different structures are fabricated using CMOS process technology by adapting transistor structures to form the diode structures. The anode regions of the photodiodes correspond to either PLDD regions of PMOS transistors or P-wells of NMOS transistors to provide two different photodiode structures with different anode region depths and thus different drift region thicknesses. An antireflective film used on the silicon surface of the photodiodes is employed as a silicide-blocking mask at other locations of the device.

Abstract: A photodetector is integrated on a single semiconductor chip with bipolar transistors including a high speed poly-emitter vertical NPN transistor. The photodetector includes a silicon nitride layer serving as an anti-reflective film. The silicon nitride layer and oxide layers on opposite sides thereof insulate edges of a polysilicon emitter from the underlying transistor regions, minimizing the parasitic capacitance between the NPN transistor's emitter and achieving a high frequency response. The method of manufacture is compatible with existing BiCMOS process technology, the silicon nitride layer of the anti-reflective film being formed over the photodetector as well as regions of the chip that include the vertical NPN transistor and other circuit elements.

Abstract: A photodetector is integrated on a single semiconductor chip with bipolar transistors including a high speed poly-emitter vertical NPN transistor. The photodetector includes a silicon nitride layer serving as an anti-reflective film. The silicon nitride layer and oxide layers on opposite sides thereof insulate edges of a polysilicon emitter from the underlying transistor regions, minimizing the parasitic capacitance between the NPN transistor's emitter and achieving a high frequency response.

Abstract: A vertical conduction NPN bipolar transistor with a tunneling barrier of silicon carbide in the emitter providing a high emitter injection efficiency and high, stable current gain. The emitter structure comprises a heavily doped polysilicon layer atop a silicon carbide layer that contacts a shallow, heavily doped emitter region at the surface of an epitaxial silicon layer, which is disposed on a monocrystallinie silicon substrate. The silicon carbide layer is about 100 to 200 angstroms thick and has a composition selected to provide an energy band gap in the 1.8 to 3.5 eV range. The thickness and composition of the silicon carbide can be varied within the preferred ranges to tune the transistor's electrical characteristics and simplify the fabrication process.