Abstract: In a method for manufacturing a micromechanical membrane structure, a doped area is created in the front side of a silicon substrate, the depth of which doped area corresponds to the intended membrane thickness, and the lateral extent of which doped area covers at least the intended membrane surface area. In addition, in a DRIE (deep reactive ion etching) process applied to the back side of the silicon substrate, a cavity is created beneath the doped area, which DRIE process is aborted before the cavity reaches the doped area. The cavity is then deepened in a KOH etching process in which the doped substrate area functions as an etch stop, so that the doped substrate area remains as a basic membrane over the cavity.

Abstract: After a p-type cladding layer, an etching rate reducing layer and a p-type contact layer are formed in order on an n-type substrate, an etching mask is formed. Then, by using the etching mask, the p-type contact layer, the etching rate reducing layer and the p-type cladding layer are partially etched in the region outside the etching mask with an etchant. At this time, the etching rate of the layers by the etchant is slower in the etching rate reducing layer than in the p-type cladding layer and the p-type contact layer. Then, a metal thin film is formed such that the film continuously coats an upper surface and side surfaces of a ridge consisting of the above layers left after the etching step. A normal vector at a surface coated with the thin film has an upward component.

Abstract: A method of fabricating a semiconductor device includes the steps of forming (or providing) a series of layers formed on a substrate, the layers including a first plurality of layers including an n-type ohmic contact layer, a p-type modulation doped quantum well structure, an n-type modulation doped quantum well structure, and a fourth plurality of layers including a p-type ohmic contact layer. Etch stop layers are used during etching operations when forming contacts to the n-type ohmic contact layer and contacts to the n-type modulation doped quantum well. Preferably, each such etch stop layer is made sufficiently thin to permit current tunneling therethrough during operation of optoelectronic/electronic devices realized from this structure (including heterojunction thyristor devices, n-channel HFET devices, p-channel HFET devices, p-type quantum-well-base bipolar transistor devices, and n-type quantum-well-base bipolar transistor devices).

Abstract: A semiconductor device having a local interconnection layer and a method for manufacturing the same are provided. A local interconnection layer is formed in an interlayer dielectric (ILD) layer on an isolation layer and a junction layer, for covering a semiconductor substrate, the isolation layer, and a gate pattern. An etch stopper pattern having at least one layer for preventing the etching of the isolation layer is formed under the local interconnection layer. The etch stopper pattern having at least one layer for preventing the etching of the isolation layer can be included when forming the local interconnection layer, thereby preventing leakage current caused by the etching of the isolation layer, improving the electrical characteristics of a semiconductor device, and improving the yield of a process of manufacturing a semiconductor device.

Abstract: A method of fabricating a semiconductor device begins by forming a lower interconnection dielectric on a substrate and forming at least one active or passive device in the lower interconnection dielectric. An etch stop layer is formed on the lower interconnection dielectric and an interconnect stack layer is formed on the etch stop layer. At least one interconnect trench structure and at least one crack stop trench are etched in the interconnect stack layer while maintaining electrical isolation between the interconnect structure and the crack stop trench.

Abstract: A method of fabricating a cladding region for use in MRAM devices includes the formation of a conductive bit line proximate to a magnetoresistive memory device. The conductive bit line is immersed in a first bath containing dissolved ions of a first conductive material for a time sufficient to displacement plate a first barrier layer on the conductive line. The first barrier layer is then immersed in an electroless plating bath to form a flux concentrating layer on the first barrier layer. The flux concentrating layer is immersed in a second bath containing dissolved ions of a second conductive material for a time sufficient to displacement plate a second barrier layer on the flux concentrating layer.

Abstract: A method of making an energy conversion device includes forming a plurality of pores within a substrate and forming a junction region within each of the plurality of pores. Each of the junction regions has a depletion region and each of the plurality of pores defines an opening size in the substrate and a spacing from adjacent pores so that the depletion regions of each of the pores is at least substantially in contact with the depletion region of the pores which are adjacent.

Abstract: A magnetic memory device, in which a tunnel magneto resistance element that establishes a connection between a write word line (first interconnection) and a bit line (second interconnection) is provided within a region in which the write word line and the bit line cross in a grade-separated manner. The magnetic memory device comprises a through hole that is provided in such a manner that is insulated from the write word line and also extending through the write word line so as to establish a connection between the tunnel magneto resistance element and a second landing pad (interconnection layer) lower than the write word line, and a contact that is formed in the through hole through a side wall barrier film so as to establish a connection between the tunnel magneto resistance element and the second landing pad.

Abstract: In one illustrative embodiment, the method comprises forming a gate insulation layer above a substrate, forming a layer of polysilicon above the gate insulation layer, implanting a dopant material into the layer of polysilicon, forming an undoped layer of polysilicon above the doped layer of polysilicon and performing an etching process on the undoped layer of polysilicon and the doped layer of polysilicon to define a gate electrode having a width at an upper surface that is greater than a width of the gate electrode at a base of the gate electrode. In further embodiments, the method comprises forming a layer of refractory metal above the gate electrode and performing at least one heating process to form a metal silicide region on the gate electrode structure.

Abstract: A graded junction termination extension in a silicon carbide (SiC) semiconductor device and method of its fabrication using ion implementation techniques is provided for high power devices. The properties of silicon carbide (SiC) make this wide band gap semiconductor a promising material for high power devices. This potential is demonstrated in various devices such as p-n diodes, Schottky diodes, bipolar junction transistors, thyristors, etc. These devices require adequate and affordable termination techniques to reduce leakage current and increase breakdown voltage in order to maximize power handling capabilities. The graded junction termination extension disclosed is effective, self-aligned, and simplifies the implementation process.

Abstract: Formation of a mixed-material composition through diffusion using photo-thermal energy. The diffusion may be used to create electrically conductive traces. The diffusion may take place between material layers on one of a package substrate, semiconductor substrate, substrate for a printed circuit board (PCB), or other multi-layered substrate. The photo-thermal energy may be supplied by various devices, for example a YAG laser device, CO2 laser device, or other energy source.

Abstract: The present invention generally relates to a method of forming a graded junction within a semiconductor substrate. A first masking pattern having a first opening characterized by a first lateral dimension is formed over the semiconductor substrate. The semiconductor substrate is doped with a first dopant, using the first masking pattern as a doping mask, thereby forming a first dopant region in the semiconductor substrate underlying the first opening. The first masking pattern is swelled to decrease the first lateral dimension of the first opening to a second lateral dimension. The semiconductor substrate is then doped with a second dopant, using the swelled first masking pattern as a doping mask, thereby forming a second dopant region in the semiconductor substrate, and furthermore defining a graded junction within the semiconductor substrate.

Abstract: A method of fabricating a flux concentrator for use in magnetic memory devices including the steps of providing at least one magnetic memory bit (10) and forming proximate thereto a material stack defining a copper (Cu) damascene bit line (56) including a flux concentrating layer (52). The method includes the steps of depositing a bottom dielectric layer (32), an optional etch stop (34) layer, and a top dielectric layer (36) proximate the magnetic memory bit (10). A trench (38) is etched in the top dielectric layer (36) and the bottom dielectric layer (32). A first barrier layer (42) is deposited in the trench (38). Next, a metal system (29) is deposited on a surface of the first barrier layer (42). The metal system (29) includes a copper (Cu) seed material (44), and a plated copper (Cu) material (46), a first outside barrier layer (50), a flux concentrating layer (52), and a second outside barrier layer (54). The metal system (29) is patterned and etched to define a copper (Cu) damascene bit line (56).

Abstract: A pn junction is formed at a to-be-etched depth in an etching region of a semiconductor body and a reverse bias voltage is applied to the pn junction to form a depletion layer. Then, the semiconductor body is etched while monitoring the reverse bias current flowing via the pn junction and a point at which the bias current has abruptly increased is determined as the etching end point.

Abstract: In one embodiment, the present invention relates to a method of etching silicon nitride disposed over a copper containing layer by etching at least a portion of the silicon nitride using a nitride etch gas mixture comprising from about 5 sccm to about 15 sccm of CHF.sub.3, about 5 sccm to about 15 sccm of nitrogen and about 80 sccm to about 120 sccm of a carrier gas. In another embodiment, the present invention relates to a method of processing a semiconductor substrate comprising silicon nitride disposed over a copper containing layer, involving etching at least a portion of the silicon nitride using a nitride etch gas mixture comprising CHF.sub.3, nitrogen and Ar.

Abstract: A method of forming interconnecting layers in a semiconductor device whereby even if a via is misaligned with a metal line, a portion of the via not enclosed and capped by the metal is enclosed and capped by an etch stop spacer. The foundation layer includes a dielectric layer having a trench formed therein, the trench being filled with a plug material. The foundation layer further includes a barrier layer formed atop the dielectric layer. A metal layer is formed on the surface of the boundary layer, and a protection layer is formed on the surface of the metal layer. The protection layer and the metal layer are patterned to define a line of composite protection/metal on the surface of the boundary layer. An etch stop layer is formed which substantially conforms to the shape of the composite protection/metal line, including etch stop spacers conforming to the sidewall portions of the line.