A method includes depositing an etch stop layer over a first conductive feature, performing a first treatment to amorphize the etch stop layer, depositing a dielectric layer over the etch stop layer, etching the dielectric layer to form an opening, etching-through the etch stop layer to extend the opening into the etch stop layer, and filling the opening with a conductive material to form a second conductive feature.

A method includes forming a semiconductor layer over a substrate; etching a portion of the semiconductor layer to form a first recess and a second recess; forming a first masking layer over the semiconductor layer; performing a first thermal treatment on the first masking layer, the first thermal treatment densifying the first masking layer; etching the first masking layer to expose the first recess; forming a first semiconductor material in the first recess; and removing the first masking layer.

Systems, apparatuses, and methods related to atom implantation for passivation of pillar material are described. An example apparatus includes a pillar of a semiconductor device. The pillar may include a first portion (e.g., a passivation material) formed from silicon nitride and an underlying second portion formed from a conductive material. A region of the first portion opposite from an interface between the first portion and the underlying second portion may be implanted with atoms of an element different from silicon (Si) and nitrogen (N) to enhance passivation of the implanted region.

A semiconductor device is provided, which includes providing an active region, a source region, a drain region, a dielectric layer, a gate structure and a nitrogen-infused dielectric layer. The source region and the drain region are formed in the active region. The dielectric layer is disposed over the source region and the drain region. The gate structure formed in the dielectric layer is positioned between the source region and the drain region. The nitrogen-infused dielectric layer is disposed over the dielectric layer and over the gate structure.

A method of manufacturing a semiconductor device includes: forming, on or above a GaN-based semiconductor layer, an electron beam resist containing chlorine; forming, in the electron beam resist, a first opening that exposes a portion of a surface of the semiconductor layer; forming a film of a shrink agent that covers a sidewall surface of the first opening; and forming, in a state in which the sidewall surface is covered by the film of the shrink agent, a Ni film that contacts the semiconductor layer through the first opening.

A method may include generating a residual curvature map for a substrate, the residual curvature map being based upon a measurement of a surface of the substrate. The method may include generating a dose map based upon the residual curvature map, the dose map being for processing the substrate using a patterning energy source; and applying the dose map to process the substrate using the patterning energy source.

A semiconductor device is disclosed in which proton implantation is performed a plurality of times to form a plurality of n-type buffer layers in an n-type drift layer at different depths from a rear surface of a substrate. The depth of the n-type buffer layer, which is provided at the deepest position from the rear surface of the substrate, from the rear surface of the substrate is more than 15 μm. The temperature of a heat treatment which is performed in order to change a proton into a donor and to recover a crystal defect after the proton implantation is equal to or higher than 400° C. In a carrier concentration distribution of the n-type buffer layer, a width from the peak position of carrier concentration to an anode is more than a width from the peak position to a cathode.

A method includes depositing an etch stop layer over a first conductive feature, performing a first treatment to amorphize the etch stop layer, depositing a dielectric layer over the etch stop layer, etching the dielectric layer to form an opening, etching-through the etch stop layer to extend the opening into the etch stop layer, and filling the opening with a conductive material to form a second conductive feature.

A method for smoothing a surface of a semiconductor portion is disclosed. In the method, an intentional oxide layer is formed on the surface of the semiconductor portion, a treated layer is formed in the semiconductor portion and inwardly of the intentional oxide layer, and then, the intentional oxide layer and the treated layer are removed to obtain a smoothed surface. The method may also be used for widening a recess in a manufacturing process for a semiconductor structure.

A semiconductor structure and a formation method thereof are provided. In one form, the method includes: providing a base; patterning the base to form a substrate and discrete fins and pseudo fins which protrude from the substrate, wherein the fins are located in a device region, and the pseudo fins are located in isolation regions; removing the pseudo fins in the isolation regions; forming isolation layers on the substrate exposed by the fins, wherein the isolation layers cover part of the side walls of the fins; and thinning the isolation layers in the isolation regions, wherein the remaining isolation layers in the isolation regions are regarded as target isolation layers, and the surfaces of the target isolation layers are lower than the surfaces of the isolation layers between the discrete fins. Since the surfaces of the target isolation layers are lower than the surfaces of the isolation layers between the discrete fins, the volume of the target isolation layers is correspondingly reduced, and then stress generated by the target isolation layers on the fins is lowered, which causes the stress on both sides of the fins to be balanced, avoids the problem of bending or tilting of the fins in the device region in case of stress imbalance and improves the electrical performance of the semiconductor structure.