Abstract: A method of etching a noble metal electrode layer disposed on a substrate to produce a semiconductor device including a plurality of electrodes separated by a distance equal to or less than about 0.35 ?m and having a noble metal profile equal to or greater than about 80°. The method comprises heating the substrate to a temperature greater than about 150° C., and etching the noble metal electrode layer by employing a high density inductively coupled plasma of an etchant gas comprising a gas selected from the group consisting of nitrogen, oxygen, a halogen (e.g., chlorine), argon, and a gas selected from the group consisting of BCl3, HBr, and SiCl4 mixtures thereof. Masking methods and etching sequences for patterning high density RAM capacitors are also provided.

Abstract: An AlxGa1−xAs/GaAs/AlxGa1−xAs quantum well exhibiting a bound-to-quasibound intersubband absorptive transition is described. The bound-to-quasibound transition exists when the first excited state has the same energy as the “top” (i.e., the upper-most energy barrier) of the quantum well. The energy barrier for thermionic emission is thus equal to the energy required for intersubband absorption. Increasing the energy barrier in this way reduces dark current. The amount of photocurrent generated by the quantum well is maintained at a high level.

Abstract: An AlxGa1−xAs/GaAs/AlxGa1−xAs quantum well exhibiting a bound-to-quasibound intersubband absorptive transition is described. The bound-to-quasibound transition exists when the first excited state has the same energy as the “top” (i.e., the upper-most energy barrier) of the quantum well. The energy barrier for thermionic emission is thus equal to the energy required for intersubband absorption. Increasing the energy barrier in this way reduces dark current. The amount of photocurrent generated by the quantum well is maintained at a high level.

Abstract: A method of etching a noble metal electrode layer disposed on a substrate to produce a semiconductor device including a plurality of electrodes separated by a distance equal to or less than about 0.35 &mgr;m and having a noble metal profile equal to or greater than about 80°. The method comprises heating the substrate to a temperature greater than about 150° C., and etching the noble metal electrode layer by employing a high density inductively coupled plasma of an etchants gas comprising a gas selected from the group consisting nitrogen, oxygen, a halogen (e.g., chlorine), argon, and a gas selected from the group consisting of BCl3, HBr, and SiCl4 mixtures thereof. A semiconductor device having a substrate and a plurality of noble metal electrodes supported by the substrate. The noble metal electrodes have a dimension (e.g., a width) which include a value equal to or less than about 0.3 &mgr;m and a platinum profile equal to or greater than about 85°.

Abstract: An AlxGa1−xAs/GaAs/AlxGa1−xAs quantum well exhibiting a bound-to-quasibound intersubband absorptive transition is described. The bound-to-quasibound transition exists when the first excited state has the same energy as the “top” (i.e., the upper-most energy barrier) of the quantum well. The energy barrier for thermionic emission is thus equal to the energy required for intersubband absorption. Increasing the energy barrier in this way reduces dark current. The amount of photocurrent generated by the quantum well is maintained at a high level.

Abstract: Improved power MOSFET structure, and fabrication process are disclosed in this invention to achieve cost savings by simplified device structure and fabrication processes, and also by reducing the required die size. Specifically, in a novel MOSFET device, insulation of mobile ions are achieved by extending the poly gate and metal contacts such that the passivation layer is no longer required and the fabrication process is simplified such that the MOSFET device can be manufactured at a lower price. Furthermore, in another MOSFET device, the gate runner is used to replace the field plate such that the requirement of a field plate as that in a conventional MOSFET device is also eliminated and, by reducing the die size, the cost of manufacture is further reduced.

Abstract: The present invention includes a substrate of a first conductivity type having a top surface including at least two intersecting trenches disposed therein with an insulating layer lining the trenches and a conductive material filling the trenches. The transistor also includes a source region of the first conductivity type extending from the top surface of the substrate adjacent to the trenches toward the substrate. The transistor further has a body region of a second conductivity type of opposite polarity from the first conductivity type, the body region extends from the top surface adjacent from the trenches to the substrate and surrounding the source region.

Abstract: This invention discloses a MOSFET device in a semiconductor chip with a top surface and a bottom surface. The MOSFET device includes a drain region, doped with impurities of a first conductivity type, formed in the semiconductor chip near the bottom surface. The MOSFET device further includes a vertical pn-junction region, which includes a lower-outer body region, doped with impurities of a second conductivity type, formed on top of the drain region. The pn-junction region further includes a source region, doped with impurities of the first conductivity type, formed on top of the lower-outer body region wherein the lower-outer body region defining a channel region extending from the source region to the drain region near the top surface. The MOSFET device further includes a gate formed on top of the channel region on the top surface. The gate includes a thin insulative bottom layer for insulating from the channel region.

Abstract: The present invention discloses a MOSFET transistor supported on a substrate. The MOSFET transistor includes an epitaxial-layer of a first conductivity type near a top surface of the substrate defining a drain region therein. The MOSFET transistor further includes an oxide block supported on a raised silicon terrace of the epitaxial layer disposed in a central portion of the transistor above a JFET reduction region of a first conductivity type of higher dopant concentration than the epitaxial layer. The MOSFET transistor further includes a lower-outer body region of a second conductivity type surrounding the JFET reduction region disposed near the top surface and defining a boundary of the MOSFET transistor. The MOSFET transistor further includes a source region of the first conductivity type enclosed in the lower-outer body region disposed near the top surface and extended to the transistor boundary.

Abstract: This invention discloses a MOSFET device which includes a plurality of vertical cells each includes a source, a drain, and a channel for conducting source-to-drain current therethrough. Each of the vertical cells is surrounded by a polysilicon layer acting as a gate for controlling the source-to-drain current through the channel. The MOSFET device further include a plurality of doping trenches filled with trench-filling materials, The MOSFET device further includes a plurality of deep-doped regions disposed underneath the doping trenches wherein the deep-doped region extends downwardly to a depth which is substantially a sum of an implant depth of the deep-doped region and a vertical diffusion depth below a bottom of the doping trenches.

Abstract: The present invention discloses a power transistor disposed on a substrate. The power device includes a core cell area comprising a plurality of power transistor cells each having drain and a source. Each of the power transistor cells further having a polycrystalline silicon gate formed on the substrate as part of a polycrystalline silicon gate layer overlaying the substrate. The polycrystalline silicon gate layer includes a plurality of polycrystalline gate-layer-extension extending to gate contact areas for forming gate contacts with a contact metal disposed thereon. The power transistor further includes a plurality of contact-metal-resistant pad each includes a thick oxide pad disposed below the gate contact areas underneath the polycrystalline gate layer extension whereby the contact-metal resistant pads resists the contact metal from penetrating therethrough and short to the substrate disposed thereunder.

Abstract: Improved power MOSFET structure, and fabrication process are disclosed in this invention to achieve higher breakdown voltage and improved device ruggedness. The power transistor includes a core cell area which includes a plurality of power transistor cells and a termination area. The power transistor further includes an outer pickup guarding ring, disposed in the termination area guarding the core cell area, for picking up free charged-particles generated in the termination area for preventing the free charged particles from entering the core cell area. In another preferred embodiment, the power transistor further includes an inner pickup guarding fence and blocks, disposed between the termination area and the core cell area for picking up free charged-particles not yet picked up by the outer pickup guarding ring for preventing the free charged particles from entering the core cell area.

Abstract: A MOSFET device formed in a semiconductor chip with a top surface and a bottom surface. The MOSFET device includes a drain region doped with impurities of a first conductivity type, formed near the bottom surface. The MOSFET device further includes a plurality of vertical cells wherein each of the vertical cell includes a vertical pn-junction zone region includes a lower-outer body region, doped with impurities of a second conductivity type, formed on top of the drain region. The pn-junction region further includes a source region, doped with impurities of the first conductivity type, formed on top of the lower-outer body region, the lower-outer body region surrounding the source region and extending to the top surface thus defining a cell area for the cell. The vertical cell further includes a source contact formed on the top surface contacting the source region. The MOSFET further includes a plurality of gates.

Abstract: Improved power MOSFET structure, and fabrication process are disclosed in this invention to achieve cost savings by simplified device structure and fabrication processes, and also by reducing the required die size. Specifically, in a novel MOSFET device, insulation of mobile ions are achieved by extending the poly gate and metal contacts such that the passivation layer is no longer required and the fabrication process is simplified such that the MOSFET device can be manufactured at a lower price. Furthermore, in another MOSFET device, the gate runner is used to replace the field plate such that the requirement of a field plate as that in a conventional MOSFET device is also eliminated and, by reducing the die size, the cost of manufacture is further reduced.

Abstract: A n-channel MOSFET device is formed with a selective high energy boron implantation into the N region of the n- channel where a photoresist is employed to cover the central portion over the channel. Small n- regions are formed near the channel source interface. These small n- regions have the advantages of preventing punch through. The selective implant regions have the additional advantages that the JFET resistance is not increased as a result of forming a punch through prevention region near the source channel boundary. Also disclosed in this invention is a p-type DMOS where a novel boron implantation is applied to reduce the threshold voltage. The boron is selectively implanted into the n-type channel near the source, i.e., a threshold sensitive region. The threshold voltage is reduced without unduly lowering the drain to source breakdown voltage.

Abstract: Improved power MOSFET structure, and fabrication process are disclosed in this invention to achieve a low threshold voltage. The improved MOSFET device is formed in a semiconductor substrate with a drain region formed near a bottom surface of the substrate supporting a plurality of double-diffused vertical cells thereon wherein each of the vertical cells including a pn-junction having a body region surrounding a source region and each of the vertical cell further including a gate above the pn-junction. Each of the vertical cells further includes a source-dopant segregation reduction layer for reducing a surface segregation between the source region and an oxide layer underneath the gate whereby the body surface peak dopant concentration near an interface between the source region and the body region is reduced for reducing a threshold voltage of the MOSFET device.

Abstract: A new DMOS fabrication process is disclosed.

Abstract: Extended cutoff wavelengths of PtSi Schottky infrared detectors in the long wavelength infrared (LWIR) regime have been demonstrated for the first time. This result was achieved by incorporating a 1-nm-thick p+ doping spike at the PtSi/Si interface. The extended cutoff wavelengths resulted from the combined effects of an increased electric field near the silicide/Si interface due to the p+ doping spike and the Schottky image force. The p+ doping spikes were grown by molecular beam epitaxy at 450 degrees Celsius using elemental boron as the dopant source, with doping concentrations ranging from 1.times.10.sup.19 to 1.times.10.sup.21 cm.sup.-3. The cutoff wavelengths were shown to increase with increasing doping concentrations of the p+ spikes.

Abstract: Amorphous Co:Si (1:2 ratio) films (12) are electron gun-evaporated on clean Si(111) substrates (10), such as in a molecular beam epitaxy system. These layers are then crystallized selectively with a focused electron beam (14) to form very small crystalline CoSi.sub.2 regions (12') in an amorphous matrix. Finally, the amorphous regions are etched away selectively using plasma or chemical techniques.

Abstract: Pinhole-free epitaxial CoSi.sub.2 films (14') are fabricated on (111)-oriented silicon substrates (10) with a modified solid phase epitaxy technique which utilizes (1) room temperature stoichiometric (1:2) codeposition of Co and Si followed by (2) room temperature deposition of an amorphous silicon capping layer (16), and (3) in situ annealing at a temperature ranging from about 500.degree. to 750.degree. C.