Abstract: A method of etching a dielectric layer comprising the following steps. A structure having the dielectric layer formed thereover is provided. A patterned photoresist layer that may be a non-aromatic positive patterned photoresist layer is formed over the dielectric layer. The patterned photoresist layer is used as a mask while etching the dielectric layer with an etching gas comprising a fluorocarbon, and may also further comprise O2, while modulating one or both select powers on and off with a duty cycle or wave form. The select powers being selected from the group consisting of an RF power and a bias power.

Abstract: A plasma etch method for forming a patterned target layer within a microelectrcnic product forms an etch residue layer adjoining a patterned mask layer formed upon a blanket target layer. After removing the patterned mask layer, the etch residue layer is laterally increased to form a laterally increased etch residue layer. The laterally increased etch residue layer is employed as an etch mask for forming the patterned target layer from the blanket target layer. The method is particularly useful for forming gate electrodes within semiconductor products.

Abstract: A process for forming a shallow trench isolation (STI), region in a strained silicon layer and in a top portion of an underlying, relaxed silicon-germanium layer, has been developed. The process features definition of a first opening in a silicon nitride stop layer via an anisotropic RIE procedure, using a photoresist shape as an etch mask. A following RIE procedure using HBr—Cl2—O2 as an etchant is next performed, defining a second opening, or a shallow trench shape opening in a strained silicon layer and in a top portion of the underlying relaxed silicon-germanium layer.

Abstract: A method of forming a composite gate structure for a planar MOSFET device, as well as for vertical, double gate, FINFET device, has been developed. The method features a composite gate structure comprised of an overlying silicon gate structure shape, and an underlying titanium nitride gate structure shape. The titanium nitride component allows a lower work function, and thus lower device operating voltages to be realized when compared to counterpart gate structures formed with only polysilicon. A novel, two step gate structure definition procedure, featuring an anisotropic first etch procedure for definition of the polysilicon gate structure shape, followed by a wet or dry isotropic second etch procedure for definition of the titanium nitride gate structure shape, is employed.

Abstract: A wet etchant solution composition and method for etching oxides of hafnium and zirconium including at least one solvent present at greater than about 50 weight percent with respect to an arbitrary volume of the wet etchant solution; at least one chelating agent present at about 0.1 weight percent to about 10 weight percent with respect to an arbitrary volume of the wet etchant solution; and, at least one halogen containing acid present from about 0.0001 weight percent to about 10 weight percent with respect to an arbitrary volume of the wet etchant solution.

Abstract: Hard mask trimming with a thin hard mask layer and a top protection layer is disclosed. During fabrication of a semiconductor device, the device has a primary layer, a lower layer, and an upper layer. The primary layer, which may be a polysilicon layer, has a critical dimension specification. The lower layer is over the polysilicon layer, and is subsequently hard mask trimmed to satisfy the critical dimension specification of the primary layer. The upper layer is over the lower layer, and has a high-etching selectivity as compared to the lower layer. The upper layer substantially prevents thickness loss of the lower layer during hard mask trimming. Each of the upper layer and the lower layer may be Si3N4, SiON, or SiO2. Additionally, the upper layer may be polysilicon.

Abstract: A method for forming a trench having upper rounded corners comprising the following steps. A substrate having an oxide layer formed thereover is provided. A hard mask layer is formed over the oxide layer. A patterned patterning layer is formed over the hard mask layer leaving one or more portions of the hard mask layer exposed. The hard mask layer is patterned using the patterned patterning layer as a mask to form a patterned hard mask layer having one or more openings exposing one or more portions of the oxide layer. The patterned patterning layer is removed. The oxide layer is patterned using the patterned hard mask layer as a mask using a first trench etching process to etch through the oxide layer at the one or more exposed portions of the oxide layer and into the substrate to form one or more shallow trenches within the substrate having upper rounded corners at the respective interfaces between substrate and patterned oxide layer.

Abstract: A process for top-corner rounding at the rim of shallow trenches of the type used for STI is described. This is achieved by first forming the trench using a silicon nitride hard mask having a layer of pad oxide between itself and the silicon surface. The silicon nitride is then briefly and selectively etched so that it pulls back from over the trench rim and exposes a small amount of the underlying pad oxide. Rounding by means of sputtering is then effected with the pad oxide serving to protect the underlying silicon until just before rounding takes place. The result is smoothly rounded corners free of facets and overhangs.

Abstract: The invention is a process for reducing variations in CD from wafer to wafer. It begins by increasing all line widths in the original pattern data file by a fixed amount that is sufficient to ensure that all lines will be wider than the lowest acceptable CD value. Using a reticle generated from this modified data file, the pattern is formed in photoresist and the resulting CD value is determined. If this turns out be outside (above) the acceptable CD range, the amount of deviation from the ideal CD value is determined and fed into suitable software that calculates the control parameters (usually time) for an ashing routine. After ashing, the lines will have been reduced in width by the amount necessary to obtain the correct CD. A fringe benefit of this trimming process is that edge roughness of the photoresist lines is reduced and line feet are removed.

Abstract: A process is described for forming very narrow polysilicon gate lines for use as gate electrodes in FETs. The process uses a consumable hard mask of silicon oxynitride covered by a thin layer of silicon oxide during the etching of the polysilicon. The thicknesses of the two layers that make up the hard mask are chosen so that the structure also serves as an ARC for the photoresist coating immediately above it. A relatively thin layer of the latter is used in order to improve resolution. After the photoresist has been patterned it may be trimmed or it may be removed and re-formed, since the silicon oxide layer provides protection for the underlying silicon oxynitride. After the hard mask has been formed, all photoresist is removed and the polysilicon is etched. During etching there is simultaneous removal of the silicon oxide layer and part of the silicon oxynitride as well.

Abstract: A plasma etch method for forming a patterned silicon containing dielectric layer within a microelectronics fabrication. There is first provided a plasma reactor chamber. There is then fixed within the plasma reactor chamber a microelectronics fabrication. The microelectronics fabrication comprises: (1) a substrate employed within the microelectronics fabrication; (2) a metal layer formed over the substrate; (3) a silicon containing dielectric layer formed upon the metal layer; and (4) a patterned photoresist layer formed upon the silicon containing dielectric layer. There is then etched through use of a plasma etch method at a first plasma reactor chamber pressure while employing the patterned photoresist layer as a photoresist etch mask layer the silicon containing dielectric layer to form a patterned silicon containing dielectric layer while reaching and etching the metal layer to form an etched metal layer.

Abstract: A method for etching bonding pad access openings in a passivation layer of an integrated circuit is described. The method utilizes a two step etching procedure wherein the first step etches isotropically through a major portion of the passivation layer under conditions which provide very high etch rate selectivities of the passivation material to the photoresist. These high selectivitities result in virtually no erosion of the photoresist while the greater part of the opening is etched. A second anisotropic etch step wherein the base of the access opening is defined faithfully replicates the dimensions of the mask pattern. This two step etch process permits the use of photoresist layers of moderate thickness as well as photoresist layers with thin regions, such as occur when the photoresist is deposited over the uneven surface topography typically found on unplanarized passivation layers.