Abstract: Embodiments of an apparatus and methods for forming thick metal interconnect structures for integrated structures are generally described herein. Other embodiments may be described and claimed.

Abstract: A method of forming a fin structure of a semiconductor device includes providing a substrate, creating a mandrel pattern over the substrate, depositing a first spacer layer over the mandrel pattern, and removing portions of the first spacer layer to form first spacer fins. The method also includes performing a first fin cut process to remove a subset of the first spacer fins, depositing a second spacer layer over the un-removed first spacer fins, and removing portions of the second spacer layer to form second spacer fins. The method further includes forming fin structures, and performing a second fin cut process to remove a subset of the fin structures.

Abstract: In a SOI process, a high lateral voltage isolation structure is formed by providing at least two concentric dielectric filled trenches, removing the semiconductor material between the dielectric filled trenches and filling the resultant gap with dielectric material to define a single wide dielectric filled trench.

Abstract: In one general aspect, an apparatus can include a trench disposed in a semiconductor region, a shield dielectric layer lining a lower portion of a sidewall of the trench and a bottom surface of the trench, and a gate dielectric lining a upper portion of the sidewall of the trench. The apparatus can also include a shield electrode disposed in a lower portion of the trench and insulated from the semiconductor region by the shield dielectric layer, and an inter-electrode dielectric (IED) disposed in the trench over the shield electrode where the shield electrode has a curved top surface.

Abstract: A method of forming a series of spaced trenches into a substrate includes forming a plurality of spaced lines over a substrate. Anisotropically etched sidewall spacers are formed on opposing sides of the spaced lines. Individual of the lines have greater maximum width than minimum width of space between immediately adjacent of the spacers between immediately adjacent of the lines. The spaced lines are removed to form a series of alternating first and second mask openings between the spacers. The first mask openings are located where the spaced lines were located and are wider than the second mask openings. Alternating first and second trenches are simultaneously etched into the substrate through the alternating first and second mask openings, respectively, to form the first trenches to be wider and deeper within the substrate than are the second trenches. Other implementations and embodiments are disclosed.

Abstract: Wafer-level processing of wafer assemblies with transducers is described herein. A method in accordance with some embodiments includes forming a solid state transducer device by forming one or more trenches to define solid state radiation transducers. An etching media is delivered in to the trenches to release the transducers from a growth substrate used to fabricate the transducers. A pad can hold the radiation transducers and promote distribution of the etching media through the trenches to underetch and release the transducers.

Abstract: A cavity is etched from a front surface into a semiconductor substrate. After providing an etch stop structure at the bottom of the cavity, the cavity is closed. From a back surface opposite to the front surface the semiconductor substrate is grinded at least up to an edge of the etch stop structure oriented to the back surface. Providing the etch stop structure at the bottom of an etched cavity allows for precisely adjusting a thickness of a semiconductor body of a semiconductor device.

Abstract: Methods for making a semiconductor device are disclosed. The method includes forming a plurality of gate stacks on a substrate, forming an etch buffer layer on the substrate, forming a dielectric material layer on the etch buffer layer, forming a hard mask layer on the substrate, wherein the hard mask layer includes one opening, and etching the dielectric material layer to form a plurality of trenches using the hard mask layer and the etch buffer layer as an etch mask.

Abstract: A phase change memory cell includes a first electrode having a cylindrical portion. A dielectric material having a cylindrical portion is longitudinally over the cylindrical portion of the first electrode. Heater material is radially inward of and electrically coupled to the cylindrical portion of the first electrode. Phase change material is over the heater material and a second electrode is electrically coupled to the phase change material. Other embodiments are disclosed, including methods of forming memory cells which include first and second electrodes having phase change material and heater material in electrical series there-between.

Abstract: Forming of filled isolation trenches, in particular the transition area in trenches and recesses free of silicon during the realization of MEMS structures of SOI wafers. A reliable dielectric insulation of adjacent silicon regions is to be obtained. The insulation is achieved by filled isolation trenches. The end portions of the trench fill that are freed from the surrounding silicon by etching are free of conductive not completely removed silicon strips in the recess including the active sensor structure. This is accomplished by slanted wall of isolation trenches. Additionally, the trench fill should be removable at the transition area in an efficient manner. The technological realization does not require specific additional process steps.

Abstract: Field Side Sub-bitline NOR-type (FSNOR) flash array and the methods of fabrication are disclosed. The field side sub-bitlines of the invention formed with the same impurity type as the memory cells' source/drain electrodes along the two sides of field trench oxide link all the source electrodes together and all the drain electrodes together, respectively, for a string of semiconductor Non-Volatile Memory (NVM) cells in a NOR-type flash array of the invention. Each field side sub-bitline is connected to a main metal bitline through a contact at its twisted point in the middle. Because there are no contacts in between the linked NVM cells' electrodes in the NOR-type flash array of the invention, the wordline pitch and the bitline pitch can be applied to the minimum geometrical feature of a specific technology node. The NOR-type flash array of the invention provides at least as high as those in the conventional NAND flash array in cell area density.

Abstract: According to example embodiments, there is provided a semiconductor device including a substrate and an isolation layer structure. The substrate includes an active region having an upper active pattern and a lower active pattern on the upper active pattern. The active region has a first aspect ratio larger than about 13:1 and a second aspect ratio smaller than about 13:1. The first aspect ratio is defined as a ratio of a sum of heights of the upper active pattern and the lower active pattern with respect to a width of the upper active pattern. The second aspect ratio is defined as a ratio of the sum of the heights of the upper active pattern and the lower active pattern with respect to a width of the lower active pattern. The isolation layer structure is adjacent to the active region.

Abstract: Embodiments of the invention provide a method of creating vias and trenches with different length. The method includes depositing a plurality of dielectric layers on top of a semiconductor structure with the plurality of dielectric layers being separated by at least one etch-stop layer; creating multiple openings from a top surface of the plurality of dielectric layers down into the plurality of dielectric layers by a non-selective etching process, wherein at least one of the multiple openings has a depth below the etch-step layer; and continuing etching the multiple openings by a selective etching process until one or more openings of the multiple openings that are above the etch-stop layer reach and expose the etch-stop layer. Semiconductor structures made thereby are also provided.

Abstract: A method for fabricating a deep trench isolation structure, wherein the method comprising steps as follows: A first hard mask layer, a second hard mask layer and a third hard mask layer are firstly formed in sequence on a substrate. The third hard mask layer is then patterned using the second hard mask layer as an etching stop layer. Subsequently, a trench etching process is performed using the patterned third hard mask layer as a mask to form a deep trench in the substrate.

Abstract: An isolation trench in a substrate of a semiconductor device includes a first shallow portion, a transition region, and a second deeper portion. The isolation trench contains a dielectric filler. The isolation trench is formed by first forming a first shallow portion of the isolation trench, forming polysilicon sidewalls on the first shallow portion, and then etching the second deeper portion.

Abstract: An isolation trench in a substrate of a semiconductor device includes a first shallow portion with a dielectric sidewall and a second deeper portion without a dielectric sidewall. The isolation trench is formed by forming a first shallow portion of the trench, forming dielectric sidewalls on the first shallow portion, and then etching the substrate below the first shallow portion to form the second deeper portion. Shallow isolation trenches may be formed simultaneously with the etching of the second deeper portion.

Abstract: A trench semiconductor power device with a termination area structure is disclosed. The termination area structure comprises a wide trench and a trenched field plate formed not only along trench sidewall but also on trench bottom of the wide trench by doing poly-silicon CMP so that the body ion implantation is blocked by the trenched field plate on the trench bottom to prevent the termination area underneath the wide trench from being implanted. Moreover, a contact mask is used to define both trenched contacts and source regions of the device for saving a source mask.

Abstract: A trench MOSFET comprising source regions having a doping profile of a Gaussian-distribution along the top surface of epitaxial layer and floating dummy cells formed between edge trench and active area is disclosed. A SBR of n region existing at cell corners renders the parasitic bipolar transistor difficult to turn on, and the floating dummy cells having no parasitic bipolar transistor act as buffer cells to absorb avalanche energy when gate bias is increasing for turning on channel, therefore, the UIS failure issue is avoided and the avalanche capability of the trench MOSFET is enhanced.

Abstract: A method of forming a semiconductor device is provided where in one embodiment an STI fill is recessed below the pad nitride and pad oxide layers, to a level substantially coplanar with the top surface of the substrate. A thin (having a thickness in the range of about 10 ?-100 ?) wet etch resistant layer is formed in contact with and completely covering at least the top surface of the recessed STI fill material. The thin wet etch resistant layer is more resistant to a wet etch process than at least the pad oxide layer. The thin wet etch resistant layer may be a refractory dielectric material, or a dielectric such as HfOx, AlyOx, ZrOx, HfZrOx, and HfSiOx. The inventive wet etch resistant layer improves the wet etch budget of subsequent wet etch processing steps.

Abstract: An array or moat isolation structure for eDRAM and methods of manufacture is provided. The method includes forming a deep trench for a memory array and an isolation region. The method includes forming a node dielectric on exposed surfaces of the deep trench for the memory array and the isolation region. The method includes filling remaining portions of the deep trench for the memory array with a metal, and lining the deep trench of the isolation region with the metal. The method includes filling remaining portions of the deep trench for the isolation region with a material, on the metal within the deep trench for the memory array. The method includes recessing the metal within the deep trench for the memory array and the isolation region. The metal in the deep trench of the memory array is recessed to a greater depth than the metal in the isolation region.

Abstract: Disclosed is a method of forming a semiconductor device structure in a semiconductor layer. The method includes forming a first trench of a first width and a second trench of a second width in the semiconductor layer; depositing a layer of first material which conforms to a wall of the first trench but does not fill it and which fills the second trench; removing the first material from the first trench, the first material remaining in the second trench; depositing a second material into and filling the first trench and over a top of the first material in the second trench; and uniformly removing the second material from the top of the first material in the second trench, wherein the first trench is filled with the second material and the second trench is filled with the first material and wherein the first material is different from the second material.

Abstract: A semiconductor structure is provided that includes a material stack including an epitaxially grown semiconductor layer on a base semiconductor layer, a dielectric layer on the epitaxially grown semiconductor layer, and an upper semiconductor layer present on the dielectric layer. A capacitor is present extending from the upper semiconductor layer through the dielectric layer into contact with the epitaxially grown semiconductor layer. The capacitor includes a node dielectric present on the sidewalls of the trench and an upper electrode filling at least a portion of the trench. A substrate contact is present in a contact trench extending from the upper semiconductor layer through the dielectric layer and the epitaxially semiconductor layer to a doped region of the base semiconductor layer. A substrate contact is also provided that contacts the base semiconductor layer through the sidewall of a trench. Methods for forming the above-described structures are also provided.

Abstract: A method of forming a series of spaced trenches into a substrate includes forming a plurality of spaced lines over a substrate. Anisotropically etched sidewall spacers are formed on opposing sides of the spaced lines. Individual of the lines have greater maximum width than minimum width of space between immediately adjacent of the spacers between immediately adjacent of the lines. The spaced lines are removed to form a series of alternating first and second mask openings between the spacers. The first mask openings are located where the spaced lines were located and are wider than the second mask openings. Alternating first and second trenches are simultaneously etched into the substrate through the alternating first and second mask openings, respectively, to form the first trenches to be wider and deeper within the substrate than are the second trenches. Other implementations and embodiments are disclosed.

Abstract: An integrated circuit containing an extended drain MOS transistor with deep semiconductor (SC) RESURF trenches in the drift region, in which each deep SC RESURF trench has a semiconductor RESURF layer at a sidewall of the trench contacting the drift region. The semiconductor RESURF layer has an opposite conductivity type from the drift region. The deep SC RESURF trenches have depth:width ratios of at least 5:1, and do not extend through a bottom surface of the drift region. A process of forming an integrated circuit with deep SC RESURF trenches in the drift region by etching undersized trenches and counterdoping the sidewall region to form the semiconductor RESURF layer. A process of forming an integrated circuit with deep SC RESURF trenches in the drift region by etching trenches and growing an epitaxial layer on the sidewall region to form the semiconductor RESURF layer.

Abstract: A method of forming trenches in a semiconductor device includes forming an etchant barrier layer above a first portion of a semiconductor layer. A first trench is etched in a second portion of the semiconductor layer using a first etchant. The second portion of the semiconductor layer is not disposed underneath the etchant barrier layer. The etchant barrier layer is etched through using a second etchant that does not substantially etch the semiconductor layer. A second trench is etched in the first portion of the semiconductor layer using a third etchant. The third etchant also extends a depth of the first trench.

Abstract: In the present invention, in the exposure to light of a memory cell array or the like of a semiconductor memory or the like, when a group of unit openings for etching the STI trench regions in which the unit openings for etching the STI trench regions each having a rectangular shape are arranged in rows and columns are transferred by the exposure onto a negative resist film, multiple exposure is appropriately used which includes a first exposure step using a first optical mask having a group of first linear openings extending in a column direction and a second exposure step using a second optical mask having a group of second linear openings extending in a row direction.

Abstract: The invention relates to a semiconductor component with trench isolation and to an associated fabrication method, a trench isolation having a deep isolation trench with a covering insulation layer, a side wall insulation layer and an electrically conductive filling layer, which is electrically connected to a predetermined doping region of the semiconductor substrate in a bottom region of the trench. The use of a trench contact, which has a deep contact trench with a side wall insulation layer and an electrically conductive filling layer, which is likewise electrically connected to the predetermined doping region of the semiconductor substrate in a bottom region of the contact trench, makes it possible to improve the electrical shielding properties with a reduced area requirement.

Abstract: In a method of forming an isolation layer, first and second trenches are formed on a substrate. The first and the second trenches have first and second widths, respectively, and the second width is greater than the first width. A second isolation layer pattern partially fills the second trench. A first isolation layer pattern and the third isolation layer pattern are formed. The first isolation layer pattern fills the first trench, and the third isolation layer pattern is formed on the second isolation layer pattern and fills a remaining portion of the second trench.

Abstract: A semiconductor device having a dual trench and methods of fabricating the same, a semiconductor module, an electronic circuit board, and an electronic system are provided. The semiconductor device includes a semiconductor substrate having a cell region including a cell trench and a peripheral region including a peripheral trench. The cell trench is filled with a core insulating material layer, and the peripheral trench is filled with a padding insulating material layer conformably formed on an inner surface thereof and a core insulating material layer formed on an inner surface of the padding insulating material layer. The core insulating material layer has a greater fluidity than the padding insulating material layer.

Abstract: Disclosed herein are various methods of forming stepped isolation structures for semiconductor devices using a spacer technique. In one example, the method includes forming a first trench in a semiconducting substrate, wherein the first trench has a bottom surface, a width and a depth, the depth of the first trench being less than a target final depth for a stepped trench isolation structure, performing an etching process through the first trench on an exposed portion of the bottom surface of the first trench to form a second trench in the substrate, wherein the second trench has a width and a depth, and wherein the width of the second trench is less than the width of the first trench, and forming the stepped isolation structure in the first and second trenches.

Abstract: A method of processing copper backside metal layer for semiconductor chips is disclosed. The backside of a semiconductor wafer, with electronic devices already fabricated on the front side, is first coated with a thin metal seed layer by either electroless plating or sputtering. Then, the copper backside metal layer is coated on the metal seed layer. The metal seed layer not only increases the adhesion between the front side metal layer and the copper backside metal layer through backside via holes, but also prevents metal peeling from semiconductor's substrate after subsequent fabrication processes, which is helpful for increasing the reliability of device performances. Suitable materials for the metal seed layer includes Pd, Au, Ni, Ag, Co, Cr, Pt, or their alloys, such as NiP, NiB, AuSn, Pt—Rh and the likes. The use of Pd as seed layer is particularly useful for the copper backside metal layer, because the Pd layer also acts as a diffusion barrier to prevent Cu atoms entering the semiconductor wafer.

Abstract: A semiconductor device includes: a semiconductor substrate having first and second areas; an STI isolation region being made of an isolation trench formed in the semiconductor substrate and an insulating film burying the isolation trench and defining a plurality of active regions in the first and second areas; a first structure formed on an area from the active region in the first area to a nearby STI isolation region and having a first height; and a second structure formed on an area from the active region in the second area to a nearby STI isolation region and having a second height, wherein the surface of the said STI isolation region in the first area is lower than the surface of said STI isolation region in the second area.

Abstract: A method for tiling selected vias in a semiconductor device is provided. The semiconductor device includes a plurality of vias. The method includes: generating a layout database for the semiconductor device; identifying isolated vias of the plurality of vias; selecting the isolated vias; defining a zone around each of the selected isolated vias; and adding tiling features on a metal layer above the selected isolated vias and within the zone. The method improves reliability of the semiconductor device by allowing moisture to vent from around the vias.

Abstract: A semiconductor device, including a semiconductor substrate including isolations defining active regions of the semiconductor substrate, and a plurality of buried gate electrodes between a pair of the isolations, wherein each of the buried gate electrodes and the isolations includes a conductive layer and a capping layer.

Abstract: A method of forming memory array and peripheral circuitry isolation includes chemical vapor depositing a silicon dioxide-comprising liner over sidewalls of memory array circuitry isolation trenches and peripheral circuitry isolation trenches formed in semiconductor material. Dielectric material is flowed over the silicon dioxide-comprising liner to fill remaining volume of the array isolation trenches and to form a dielectric liner over the silicon dioxide-comprising liner in at least some of the peripheral isolation trenches. The dielectric material is furnace annealed at a temperature no greater than about 500° C. The annealed dielectric material is rapid thermal processed to a temperature no less than about 800° C. A silicon dioxide-comprising material is chemical vapor deposited over the rapid thermal processed dielectric material to fill remaining volume of said at least some peripheral isolation trenches.

Abstract: Methods of forming a semiconductor trench and forming dual trenches and a structure for isolating devices are provided. The structure for isolating devices is disposed in a substrate having a periphery area and an array area. The structure for isolating devices includes a first isolation structure and a second isolation structure. The first isolation structure has a profile with at least three steps and is disposed in the substrate in the periphery area. The second isolation structure has a profile with at least two steps and is disposed in the substrate in the array area.

Abstract: A semiconductor device having a buried gate that can realize a reduction in gate-induced drain leakage is presented. The semiconductor device includes a semiconductor substrate, a buried gate, and a barrier layer. The semiconductor substrate has a groove. The buried gate is formed in a lower portion of the groove and has a lower portion wider than an upper portion. The barrier layer is formed on sidewalls of the upper portion of the buried gate.

Abstract: Field Side Sub-bitline NOR-type (FSNOR) flash array and the methods of fabrication are disclosed. The field side sub-bitlines of the invention formed with the same impurity type as the memory cells' source/drain electrodes along the two sides of field trench oxide link all the source electrodes together and all the drain electrodes together, respectively, for a string of semiconductor Non-Volatile Memory (NVM) cells in a NOR-type flash array of the invention. Each field side sub-bitline is connected to a main metal bitline through a contact at its twisted point in the middle. Because there are no contacts in between the linked NVM cells' electrodes in the NOR-type flash array of the invention, the wordline pitch and the bitline pitch can be applied to the minimum geometrical feature of a specific technology node. The NOR-type flash array of the invention provides at least as high as those in the conventional NAND flash array in cell area density.

Abstract: A shallow trench isolation (STI) structure and methods of forming a STI structure are disclosed. An embodiment is a method for forming a semiconductor structure. The method includes forming a recess in a semiconductor substrate; forming a first material on sidewalls of the recess; forming a widened recessed portion through a bottom surface of the recess; removing the first material from the sidewalls of the recess; and forming a dielectric material in the recess and the widened recessed portion. The bottom surface of the recess is exposed through the first material, and the bottom surface of the recess has a first width. The widened recessed portion has a second width. The second width is greater than the first width.

Abstract: System and method for implementing multi-resolution advanced process control (“APC”) are described. One embodiment is a method including obtaining low resolution metrology data and high resolution metrology data related to a process module for performing a process on the wafer. A process variable of the process is modeled as a function of the low resolution metrology data to generate a low-resolution process model and the process variable is modeled as a function of the high resolution metrology data to generate a high-resolution process model.

Abstract: A method of forming a series of spaced trenches into a substrate includes forming a plurality of spaced lines over a substrate. Anisotropically etched sidewall spacers are formed on opposing sides of the spaced lines. Individual of the lines have greater maximum width than minimum width of space between immediately adjacent of the spacers between immediately adjacent of the lines. The spaced lines are removed to form a series of alternating first and second mask openings between the spacers. The first mask openings are located where the spaced lines were located and are wider than the second mask openings. Alternating first and second trenches are simultaneously etched into the substrate through the alternating first and second mask openings, respectively, to form the first trenches to be wider and deeper within the substrate than are the second trenches. Other implementations and embodiments are disclosed.

Abstract: A method for fabricating a semiconductor device includes: providing a substrate; forming a plurality of trenches by etching the substrate; forming a first isolation layer by filling the plurality of the trenches with a first insulation layer; recessing the first insulation layer filling a first group of the plurality of the trenches to a predetermined depth; forming a liner layer over the first group of the trenches with the first insulation layer recessed to the predetermined depth; and forming a second isolation layer by filling the first group of the trenches, where the liner layer is formed, with a second insulation layer.

Abstract: A method of forming trench isolation with different depths of a semiconductor device is disclosed. A semiconductor substrate having a first mask layer formed thereon is first provided. A first etching process is performed with the first mask layer as an etching mask to form a shallow trench structure, followed by forming a first dielectric layer on the semiconductor substrate to fill the shallow trench structure. The first dielectric layer is then patterned to form a second mask layer which is used in a second etching process to form a deep trench structure. After that, a dielectric material is applied to fill the deep trench structure.

Abstract: A method for fabricating a semiconductor device with improved performance is disclosed. The method comprises providing a substrate including a first region and a second region; forming at least one isolation region having a first aspect ratio in the first region and at least one isolation region having a second aspect ratio in the second region; performing a high aspect ratio deposition process to form a first layer over the first and second regions of the substrate; removing the first layer from the second region; and performing a high density plasma deposition process to form a second layer over the first and second regions of the substrate.

Abstract: Provided is a method of forming an isolation structure of a semiconductor device capable of minimizing the number of performing a patterning process and having trenches of various depths. The method includes partially etching the semiconductor substrate using a first patterning process to form first trenches and second trenches having a first depth. The semiconductor substrate has first to third regions. The first trenches are formed in the first region, and the second trenched are formed in the second region. The semiconductor substrate is partially etched using a second patterning process, so that third trenches are formed in the third region, and fourth trenches are formed in the second region. The fourth trenches extend from bottoms of the second trenches. The third trenches have a second depth, and the fourth trenches have a third depth. An isolation layer filling the first to fourth trenches is formed.

Abstract: A semiconductor structure and method of manufacturing the semiconductor structure, and more particularly to a semiconductor structure having reduced metal line resistance and a method of manufacturing the same in back end of line (BEOL) processes. The method includes forming a first trench extending to a lower metal layer Mx+1 and forming a second trench remote from the first trench. The method further includes filling the first trench and the second trench with conductive material. The conductive material in the second trench forms a vertical wiring line extending orthogonally and in electrical contact with an upper wiring layer and electrically isolated from lower metal layers including the lower metal layer Mx+1. The vertical wiring line decreases a resistance of a structure.

Abstract: An isolation structure comprising a substrate is provided. A trench is in the substrate. A sidewall of the trench has a first inclined surface and a second inclined surface. The first inclined surface is located on the second inclined surface. The slope of the first inclined surface is different from the slope of the second inclined surface. A length of the first inclined surface is greater than 15 nanometers.

Abstract: A peripheral circuit area is formed around a memory cell array area. The peripheral circuit area has element regions, an element isolation region isolating the element regions, and field-effect transistor formed in each of the element regions and including a gate electrode extending in a channel width direction, on a semiconductor substrate. An end portion and a corner portion of the gate electrode are on the element isolation region. A radius of curvature of the corner portion of the gate electrode is smaller than a length from the end portion of the element region in the channel width direction to the end portion of the gate electrode in the channel width direction, and is less than 85 nm.

Abstract: A dielectric liner is formed in first and second trenches respectively in first and second portions of a substrate. A layer of material is formed overlying the dielectric liner so as to substantially concurrently substantially fill the first trench and partially fill the second trench. The layer of material is removed substantially concurrently from the first and second trenches to expose substantially all of the dielectric liner within the second trench and to form a plug of the material in the one or more first trenches. A second layer of dielectric material is formed substantially concurrently on the plug in the first trench and on the exposed portion of the dielectric liner in the second trench. The second layer of dielectric material substantially fills a portion of the first trench above the plug and the second trench.

Abstract: A photon collector has a reflecting metal layer to increase photon collection efficiency in a solid state imaging sensor. The reflecting metal layer reflects incident light internally to a photosensor. A plurality of photon collectors is formed in a wafer substrate over an array of photosensors. The photon collector is formed in an opening in an insulating layer provided over each photosensor.