A method for forming a semiconductor device is provided. The method for forming a semiconductor device is provided. The method includes coating a photoresist film over a target layer; performing a lithography process to pattern the photoresist film into a photoresist layer; performing a directional ion bombardment process to the photoresist layer, such that a carbon atomic concentration in the photoresist layer is increased; and etching the target layer using the photoresist layer as an etch mask.

An apparatus for perform metal etching and plasma ashing includes: a processing chamber having an enclosed area; an electrostatic chuck disposed in the enclosed area and configured to secure a wafer, the electrostatic chuck connected with a bias power; at least one coil connected with a source power; a etchant conduit configured provide an etchant to a metal of the wafer within the processing chamber in accordance with a photoresist mask of the wafer; and a gas intake conduit connected with a gas source, wherein the gas intake conduit is configured to supply the processing chamber with a gas from the gas source during performance of plasma ashing within the processing chamber.

Techniques herein include methods for forming a direct write, tunable stress film and methods for correcting wafer bow using said stress film. The method can be executed on a coater-developer tool or track-based tool. The stress film can be based on a film that undergoes crosslinking/decrosslinking under external stimulus where direct write is achieved by, but is not limited to, 365 nm exposure and subsequent cure is used to “pattern-in” stress. No develop step may be required, which provides additional significant benefit in conserving film planarity. An amount of bow (or internal stress to create or affect a bow signature) can be tuned with exposure dose, bake temperature, bake time and number of bakes.

A vertical capacitor structure includes a substrate, at least a pillar, a first conductive layer, a first dielectric layer and a second conductive layer. The substrate defines a cavity. The pillar is disposed in the cavity. The first conductive layer covers and is conformal to the cavity of the substrate and the pillar, and is insulated from the substrate. The first dielectric layer covers and is conformal to the first conductive layer. The second conductive layer covers and is conformal to the first dielectric layer. The first conductive layer, the first dielectric layer and the second conductive layer jointly form a capacitor component.

A wafer having a first region and a second region is provided. A first topography variation exists between the first region and the second region. A first layer is formed over the first region and over the second region of the wafer. The first layer is patterned. A patterned first layer causes a second topography variation to exist between the first region and the second region. The second topography variation is smoother than the first topography variation. A second layer is formed over the first region and the second region. At least a portion of the second layer is formed over the patterned first layer.

A method of deposition is disclosed. The method can include dispensing a formable material over a substrate, where the substrate includes a non-uniform surface topography, and where the substrate includes an active zone and an exclusion zone. The method can also include curing the formable material in the exclusion zone to form a circular edge between the exclusion zone and the active zone, contacting the formable material with a superstrate, and curing the formable material in the active zone to form a layer over the substrate, wherein curing is performed while the superstrate is contacting the formable material.

A self-assembled nanostructure comprises first domains and second domains. The first domains comprise a first block of a block copolymer material and an activatable catalyst. The second domains comprise a second block and substantially without the activatable catalyst. The activatable catalyst is capable of generating catalyst upon application of activation energy, and the generated catalyst is capable of reacting with a metal oxide precursor to provide a metal oxide. A semiconductor structure comprises such self-assembled nanostructure on a substrate.

A method for forming a semiconductor device structure is provided. The method includes forming a dielectric layer over a substrate. The substrate has a fin structure, and the dielectric layer has a trench exposing a portion of the fin structure. The method includes forming a gate material layer in the trench. The method includes forming a planarization layer over the gate material layer. The planarization layer includes a first material that is different from a second material of the gate material layer and a third material of the dielectric layer. The method includes performing an etching process to remove the planarization layer and a first upper portion of the gate material layer so as to form a gate in the trench.

Cyclic etch methods comprise the steps of: i) exposing a SiN layer covering a structure on a substrate in a reaction chamber to a plasma of hydrofluorocarbon (HFC) to form a polymer layer deposited on the SiN layer that modifies the surface of the SiN layer, the HFC having a formula C.sub.xH.sub.yF.sub.z where x=2-5, y>z, the HFC being a saturated or unsaturated, linear or cyclic HFC; ii) exposing the polymer layer deposited on the SiN layer to a plasma of an inert gas, the plasma of the inert gas removing the polymer layer deposited on the SiN layer and the modified surface of the SiN layer on an etch front; and iii) repeating the steps of i) and ii) until the SiN layer on the etch front is selectively removed, thereby forming a substantially vertically straight SiN spacer comprising the SiN layer on the sidewall of the structure.

A variety of footed and leadless semiconductor packages, with either exposed or isolated die pads, are described. Some of the packages have leads with highly coplanar feet that protrude from a plastic body, facilitating mounting the packages on printed circuit boards using wave-soldering techniques.