Abstract: A method of forming a semiconductor device, including forming a first semiconductor layer on a semiconductor substrate, the first semiconductor layer being of the same dopant type as the semiconductor substrate, the first semiconductor layer having a higher dopant concentration than the semiconductor substrate, increasing the porosity of the first semiconductor layer, first annealing the first semiconductor layer at a temperature of at least 1050° C., forming a second semiconductor layer on the first semiconductor layer and separating the second semiconductor layer from the semiconductor substrate by splitting within the first semiconductor layer.

Abstract: A layered structure for semiconductor application is described herein. The layered structure includes a starting material and a fully depleted porous layer formed over the starting material with high resistivity. In some embodiments, the layered structure further includes epitaxial layer grown over the fully depleted porous layer. Additionally, a process of making the layered structure including forming the fully depleted porous layer and epitaxial layer grown over the porous layer is described herein.

Abstract: In a method of forming a groove pattern extending in a first axis in an underlying layer over a semiconductor substrate, a first opening is formed in the underlying layer, and the first opening is extended in the first axis by directional etching to form the groove pattern.

Abstract: Methods of forming a semiconductor device are provided. A method includes introducing impurities into a part of a semiconductor substrate at a first surface of the semiconductor substrate by ion implantation, the impurities being configured to absorb electromagnetic radiation of an energy smaller than a bandgap energy of the semiconductor substrate. The method further includes forming a semiconductor layer on the first surface of the semiconductor substrate. The method further includes irradiating the semiconductor substrate with electromagnetic radiation configured to be absorbed by the impurities and configured to generate local damage of a crystal lattice of the semiconductor substrate. The method further includes separating the semiconductor layer and the semiconductor substrate by thermal processing of the semiconductor substrate and the semiconductor layer, where the thermal processing is configured to cause crack formation along the local damage of the crystal lattice by thermo-mechanical stress.

Abstract: A surface-mount chip is formed by a silicon substrate having a front surface and a side. The chip includes a metallization intended to be soldered to an external device. The metallization has a first portion covering at least a portion of the front surface of the substrate and a second portion covering at least a portion of the side of the substrate. A porous silicon region is included in the substrate to separating the second portion of the metallization from the rest of the substrate.

Abstract: A method of fabricating non-tilted, electrically isolated fins from a bulk substrate is provided. A plurality of semiconductor fins is formed extending upwards from a remaining portion of a bulk semiconductor substrate. Each semiconductor fin includes a hard mask cap. A sacrificial dielectric material portion is formed between each semiconductor fin, wherein each sacrificial dielectric material portion has a topmost surface that is vertically offset and located below a topmost surface of each hard mask cap. An anchoring structure having an opening is then formed atop each sacrificial dielectric material portion and each hard mask cap. Next, an entirety of each sacrificial dielectric material portion is removed by etching through the opening. An oxide layer is then formed within an upper portion of the remaining portion of the bulk semiconductor substrate, wherein a portion of the oxide layer extends beneath each semiconductor fin. Next, the anchoring structure is removed.

Abstract: A method of manufacturing an order vacancy compound (OVC) is provided. The method includes the following steps. A trivalent ion, a hexavalent ion and one of a univalent ion and a bivalent ion for an electrodeposition process are provided to form a solar energy absorbing film. The OVC is formed by performing an electrochemical etching process on the solar energy absorbing film.

Abstract: In sophisticated semiconductor devices, replacement gate approaches may be applied in combination with a process strategy for implementing a strain-inducing semiconductor material, wherein superior proximity of the strain-inducing semiconductor material and/or superior robustness of the replacement gate approach may be achieved by forming the initial gate electrode structures with superior uniformity and providing at least one cavity for implementing the strained channel regions in a very advanced manufacturing stage, i.e., after completing the basic transistor configuration.

Abstract: Integrated circuit devices include a semiconductor substrate having a plurality of trench isolation regions therein that define respective semiconductor active regions therebetween. A trench is provided in the semiconductor substrate. The trench has first and second opposing sidewalls that define opposing interfaces with a first trench isolation region and a first active region, respectively. A first electrical interconnect is provided at a bottom of the trench. An electrically insulating capping pattern is provided, which extends between the first electrical interconnect and a top of the trench. An interconnect insulating layer is also provided, which lines the first and second sidewalls and bottom of the trench. The interconnect insulating layer extends between the first electrical interconnect and the first active region. A recess is provided in the first active region. The recess has a sidewall that defines an interface with the interconnect insulating layer.

Abstract: A simple and cost-effective form of implementing a semiconductor component having a micromechanical microphone structure, including an acoustically active diaphragm as a deflectable electrode of a microphone capacitor, a stationary, acoustically permeable counterelement as a counter electrode of the microphone capacitor, and means for applying a charging voltage between the deflectable electrode and the counter electrode of the microphone capacitor. In order to not impair the functionality of this semiconductor component, even during overload situations in which contact occurs between the diaphragm and the counter electrode, the deflectable electrode and the counter electrode of the microphone capacitor are counter-doped, at least in places, so that they form a diode in the event of contact. In addition, the polarity of the charging voltage between the deflectable electrode and the counter electrode is such that the diode is switched in the blocking direction.

Abstract: A method for forming a silicon layer according to inventive concept comprises: preparing an SOI substrate; applying an etchant or vapor of the etchant to the SOI substrate; and irradiating a light to the SOI substrate.

Abstract: Monocrystalline semiconductor substrates are textured with alkaline solutions to form pyramid structures on their surfaces to reduce incident light reflectance and improve light absorption of the wafers. The alkaline baths include hydantoin compounds and derivatives thereof in combination with alkoxylated glycols to inhibit the formation of flat areas between pyramid structures to improve the light absorption.

Abstract: A micromechanical systems (MEMs) pressure sensor includes a semiconductor substrate having a deep well located within a first surface and a cavity located within a second, opposing surface. The semiconductor substrate has a first doping type. The deep well has a second doping type, with a gradient doping profile, thereby forming a PN junction within the substrate. The cavity forms a diaphragm, which is a substrate section that is thinner than the surrounding substrate sections, that comprises the deep well. One or more pizeoresistor elements are located within the deep well. The piezoresistors are sensitive to deformations, such as bending, in the diaphragm caused by changes in the pressure of the cavity.

Abstract: In sophisticated semiconductor devices, replacement gate approaches may be applied in combination with a process strategy for implementing a strain-inducing semiconductor material, wherein superior proximity of the strain-inducing semiconductor material and/or superior robustness of the replacement gate approach may be achieved by forming the initial gate electrode structures with superior uniformity and providing at least one cavity for implementing the strained channel regions in a very advanced manufacturing stage, i.e., after completing the basic transistor configuration.

Abstract: A method for fabricating a semiconductor device includes forming a fuse over a substrate, the fuse having a barrier layer, a metal layer, and an anti-reflective layer stacked, selectively removing the anti-reflective layer, forming an insulation layer over a whole surface of the resultant structure including the fuse, and performing repair-etching such that part of the insulation layer remains above the fuse.

Abstract: A capacitive electromechanical transducer includes a substrate, a cavity formed by a vibrating membrane held above the substrate with a certain distance between the vibrating membrane and the substrate by supporting portions arranged on the substrate, a first electrode whose surface is exposed to the cavity, and a second electrode whose surface facing the cavity is covered with an insulating film, wherein the first electrode is provided on a surface of the substrate or a lower surface of the vibrating membrane and the second electrode is provided on a surface of the vibrating membrane or a surface of the substrate so as to face the first electrode. In this transducer, fine particles composed of an oxide film of a substance constituting the first electrode are arranged on the surface of the first electrode, and the diameter of the fine particles is 2 to 200 nm.

Abstract: Integrated circuit devices include a semiconductor substrate having a plurality of trench isolation regions therein that define respective semiconductor active regions therebetween. A trench is provided in the semiconductor substrate. The trench has first and second opposing sidewalls that define opposing interfaces with a first trench isolation region and a first active region, respectively. A first electrical interconnect is provided at a bottom of the trench. An electrically insulating capping pattern is provided, which extends between the first electrical interconnect and a top of the trench. An interconnect insulating layer is also provided, which lines the first and second sidewalls and bottom of the trench. The interconnect insulating layer extends between the first electrical interconnect and the first active region. A recess is provided in the first active region. The recess has a sidewall that defines an interface with the interconnect insulating layer.

Abstract: A single crystal silicon etching method includes providing a single crystal silicon substrate having at least one trench therein. The single crystal silicon substrate is exposed to an anisotropic etchant that undercuts the single crystal silicon. By controlling the length of the etch, single crystal silicon islands or smooth vertical walls in the single crystal silicon may be created.

Abstract: Method for the electrochemical etching of macropores in n-type silicon wafers, using illumination of the wafer reverse sides and using an aqueous electrolyte, characterized in that the electrolyte is an aqueous acetic acid solution with the composition of H2O: CH3COOH in the range between 2:1 and 7:3, with an addition of at least 9 percent by weight hydrofluoric acid.

Abstract: Methods for forming an ultra thin structure using a method that includes multiple cycles of polymer deposition of photoresist (PDP) process and etching process. The embodiments described herein may be advantageously utilized to fabricate a submicron structure on a substrate having a critical dimension less than 55 nm and beyond. In one embodiment, a method of forming a submicron structure on a substrate may include providing a substrate having a patterned photoresist layer disposed on a film stack into an etch chamber, wherein the film stack includes at least a hardmask layer disposed on a dielectric layer, performing a polymer deposition process to deposit a polymer layer on the pattered photoresist layer, thus reducing a critical dimension of an opening in the patterned photoresist layer, and etching the underlying hardmask layer through the opening having the reduced dimension.

Abstract: A light-emitting device is capable of emitting a light having a wavelength ranging from 300 to 550 nm, and includes: a substrate; a p-type semiconductor layer disposed on the substrate; an active layer disposed on the p-type semiconductor layer; a n-type semiconductor layer disposed on the active layer and having a waveguide-disposing surface; and a waveguide structure formed on the waveguide-disposing surface of the n-type semiconductor layer and having a plurality of spaced apart nanorods extending from the waveguide-disposing surface.

Abstract: A method of fabricating a microchannel plate includes forming a plurality of pores in a silicon substrate. The plurality of pores is oxidized, thereby consuming silicon at surfaces of the plurality of pores and forming a silicon dioxide layer over the plurality of pores. At least a portion of the silicon dioxide layer is stripped, which reduces a surface roughness of the plurality of pores. A semiconducting layer can be deposited onto the surface of the silicon dioxide layer. The semiconducting layer is then oxidized, thereby consuming at least some of the polysilicon or amorphous silicon layer and forming an insulating layer. Resistive and secondary electron emissive layers are then deposited on the insulating layer by atomic layer deposition.

Abstract: A single crystal silicon etching method includes providing a single crystal silicon substrate having at least one trench therein. The single crystal silicon substrate is exposed to an anisotropic etchant that undercuts the single crystal silicon. By controlling the length of the etch, single crystal silicon islands or smooth vertical walls in the single crystal silicon may be created.

Abstract: Described is a method for manufacturing a micromechanical sensor element and a micromechanical sensor element manufactured in particular using such a method which has a hollow space or a cavity and a membrane for detecting a physical variable. Different method steps are performed for manufacturing the sensor element, among other things, a structured etch mask having a plurality of holes or apertures being applied on a semiconductor substrate. Moreover, an etch process is used to create depressions in the semiconductor substrate beneath the holes in the structured etch mask. Anodization of the semiconductor material is subsequently carried out, the anodization taking place preferably starting from the created depressions in the semiconductor substrate. Due to this process, porous areas are created beneath the depressions, a lattice-like structure made of untreated, i.e., non-anodized, substrate material remaining between the porous areas and the depressions.

Abstract: A method and apparatus for the removal of a deposited conductive layer along an edge of a substrate using a power ring configured to electro polish an edge of the substrate are provided. The electro polishing of the substrate edge may occur simultaneously with the electrochemical mechanical processing of a substrate face. In certain embodiments a method of electrochemically polishing a substrate having a conductive material disposed thereon is provided. A substrate is coupled with a carrier head comprising a power ring which surrounds an edge of the substrate, wherein the edge of the substrate includes the conductive material. A polishing pad is contacted with a face of the substrate. A first voltage is applied to the power ring to remove conductive material from the edge of the substrate. A second voltage different from the first voltage is applied to the polishing pad to remove a portion of the conductive material from the face of the substrate.

Abstract: A retaining ring for use with electrochemical mechanical processing is described. The retaining ring has a generally annular body formed with a conductive portion and a non-conductive portion. The non-conductive portion contacts the substrate during polishing. The conductive portion is electrically biased during polishing to reduce the edge effect that tends to occur with conventional electrochemical mechanical processing systems.

Abstract: In an integrated pressure sensor including a semiconductor substrate having a p type single crystal silicon substrate and an n type epitaxial layer of which a portion is etched by electrochemical etching to have a diaphragm, an impurity diffusion layer piercing the n type epitaxial layer at least defining the diaphragm is formed for isolation. An etching wire is formed on the surface of the n type epitaxial layer with insulation and the first end of the etching wire extends to the inside of the surface and connected to the n type epitaxial layer. The second opposite end extends to an edge of the semiconductor substrate. The etching wire does not cross the impurity layer inside the surface of the semiconductor substrate to prevent the etching wire from short-circuiting with the impurity diffusion layer during the electrochemical etching.