Patent application number | Description | Published |
20080224255 | SUBGROUND RULE STI FILL FOR HOT STRUCTURE - This invention provides a hybrid orientation (HOT) semiconductor-on-insulator (SOI) structure having an isolation region, e.g. a shallow trench isolation region (STI), and a method for forming the STI structure that is easy to control. The method of forming the isolation region includes an etch of the insulating material, selective to the semiconductor material, followed by an etch of the semiconductor material, selective to the insulating material, and then filling any high aspect ratio gaps with a CVD oxide, and filling the remainder of the STI with an HDP oxide. | 09-18-2008 |
20090047791 | SEMICONDUCTOR ETCHING METHODS - A method of etching semiconductor structures is disclosed. The method may include etching an SRAM portion of a semiconductor device, the method comprising: providing a silicon substrate layer, a nitride layer thereover, an optical dispersive layer over the nitride layer, and a silicon anti-reflective coating layer thereover; etching the silicon anti-reflective coating layer using an image layer; removing the image layer; etching the optical dispersive layer while removing the silicon anti-reflective coating layer; etching the optical dispersive layer and the nitride layer simultaneously; and etching the optical dispersive layer, the nitride layer, and the silicon substrate simultaneously. | 02-19-2009 |
20090079027 | SHALLOW TRENCH ISOLATION STRUCTURE COMPATIBLE WITH SOI EMBEDDED DRAM - A deep trench is formed in a semiconductor-on-insulator (SOI) substrate and a pad layer thereupon. A conductive trench fill region is formed in the deep trench. A planarizing material layer having etch selectivity relative to the pad layer is applied. A portion of the pad layer having an edge that is vertically coincident with a sidewall of the deep trench is exposed by lithographic means. Exposed portion of the pad layer are removed selective to the planarizing material layer, followed by removal of exposed portion of a semiconductor layer selective to the conductive trench fill region by an anisotropic etch. The planarizing material layer is removed and a shallow trench isolation structure having a lower sidewall that is self-aligned to an edge of the original deep trench is formed. Another shallow trench isolation structure may be formed outside the deep trench concurrently. | 03-26-2009 |
20090104776 | METHODS FOR FORMING NESTED AND ISOLATED LINES IN SEMICONDUCTOR DEVICES - A method for forming lines for semiconductor devices including, depositing a shallow trench isolation (STI) film stack on a silicon substrate, depositing a layer of polysilicon on the STI film stack, depositing a layer of antireflective coating on the layer of polysilicon, developing a phototoresist on the antireflective coating, wherein the photoresist defines a line, etching the layer of antireflective coating and the layer of polysilicon using RIE with a low bias power, removing the photoresist, removing the layer of antireflective coating, etching the STI film stack to form the line, wherein the layer of polysilicon further defines the line. | 04-23-2009 |
20090189242 | METHOD FOR NON-SELECTIVE SHALLOW TRENCH ISOLATION REACTIVE ION ETCH FOR PATTERNING HYBRID-ORIENTED DEVICES COMPATIBLE WITH HIGH-PERFORMANCE HIGHLY-INTEGRATED LOGIC DEVICES - Disclosed are embodiments of a hybrid-orientation technology (HOT) wafer and a method of forming the HOT wafer with improved shallow trench isolation (STI) structures for patterning devices in both silicon-on-insulator (SOI) regions, having a first crystallographic orientation, and bulk regions, having a second crystallographic orientation. The improved STI structures are formed using a non-selective etch process to ensure that all of the STI structures and, particularly, the STI structures at the SOI-bulk interfaces, each extend to the semiconductor substrate and have an essentially homogeneous (i.e., single material) and planar (i.e., divot-free) bottom surface that is approximately parallel to the top surface of the substrate. Optionally, an additional selective etch process can be used to extend the STI structures a predetermined depth into the substrate. | 07-30-2009 |
20100193852 | EMBEDDED DRAM MEMORY CELL WITH ADDITIONAL PATTERNING LAYER FOR IMPROVED STRAP FORMATION - The present invention relates to semiconductor devices, and more particularly to a structure and method for forming memory cells in a semiconductor device using a patterning layer and etch sequence. The method includes forming trenches in a layered semiconductor structure, each trench having an inner sidewall adjacent a section of the layered semiconductor structure between the trenches and an outer sidewall opposite the inner sidewall. The trenches are filled with polysilicon and the patterning layer is formed over the layered semiconductor structure. An opening is then patterned through the patterning layer, the opening exposing the section of the layered semiconductor structure between the trenches and only a vertical portion of the polysilicon along the inner sidewall of each trench. The layered semiconductor structure is then etched. The patterning layer prevents a second vertical portion of the polysilicon along the outer sidewall of each trench from being removed. By adding the patterning layer over the semiconductor structure during trench type memory cell fabrication, strap resistance and its variation can be reduced, resulting in better DRAM cell operation with less process dependence and improved strap overlay formation. | 08-05-2010 |
20120086064 | METHOD OF FORMING ENHANCED CAPACITANCE TRENCH CAPACITOR - A method of fabricating a trench capacitor is provided in which a material composition of a semiconductor region of a substrate varies in a quantity of at least one component therein such that the quantity alternates with depth a plurality of times between at least two different values. For example, a concentration of a dopant or a weight percentage of a second semiconductor material in a semiconductor alloy can alternate between with depth a plurality of times between higher and lower values. In such method, the semiconductor region can be etched in a manner dependent upon the material composition to form a trench having an interior surface which undulates in a direction of depth from the major surface of the semiconductor region. Such method can further include forming a trench capacitor having an undulating capacitor dielectric layer, wherein the undulations of the capacitor dielectric layer are at least partly determined by the undulating interior surface of the trench. Such trench capacitor can provide enhanced capacitance, and can be incorporated in a memory cell such as a dynamic random access memory (“DRAM”) cell, for example. | 04-12-2012 |
20120187465 | ENHANCED CAPACITANCE TRENCH CAPACITOR - An integrated circuit including a trench capacitor has a semiconductor region in which a material composition varies in a quantity of at least one component therein such that the quantity alternates with depth a plurality of times between at least two different values. For example, a concentration of a dopant or a weight percentage of a second semiconductor material, such as germanium, in a semiconductor alloy can alternate between with depth a plurality of times between higher and lower values. The trench capacitor has an undulating capacitor dielectric layer, wherein the undulations of the capacitor dielectric layer are at least partly determined by the undulating interior surface of the trench. Such trench capacitor can provide enhanced capacitance, and can be incorporated in a memory cell such as a dynamic random access memory (“DRAM”) cell, for example. | 07-26-2012 |
20130228840 | EMBEDDED DRAM MEMORY CELL WITH ADDITIONAL PATTERNING LAYER FOR IMPROVED STRAP FORMATION - A method of forming a memory cell including forming trenches in a layered semiconductor structure, each trench having an inner sidewall adjacent a section of the layered semiconductor structure between the trenches and an outer sidewall opposite the inner sidewall. The trenches are filled with polysilicon and the patterning layer is formed over the layered semiconductor structure. An opening is then patterned through the patterning layer, the opening exposing the section of the layered semiconductor structure between the trenches and only a vertical portion of the polysilicon along the inner sidewall of each trench. The layered semiconductor structure is then etched. The patterning layer prevents a second vertical portion of the polysilicon along the outer sidewall of each trench from being removed. | 09-05-2013 |