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.

Embodiments of the present disclosure generally relate to a layer stack including a high K dielectric layer formed over a first dielectric layer and a metal electrode. The high K dielectric layer has a K value of 20 or higher and may be formed as a part of a capacitor, a gate insulating layer, or any suitable insulating layer in electronic devices, such as display devices. The layer stack includes a second dielectric layer disposed on the first dielectric layer and the metal layer, and the high K dielectric layer containing zirconium dioxide or hafnium dioxide disposed on the second dielectric layer. The second dielectric layer provides a homogenous surface on which the high K dielectric layer is formed. The homogeneous surface enables the high K dielectric material to be deposited uniformly thereover, resulting in a uniform thickness profile.

The present disclosure relates to a method and device for decreasing generation of surface oxide of aluminum nitride. In a physical vapor deposition process, the aluminum nitride is deposited on a substrate in a deposition chamber to form an aluminum nitride coated substrate. A cooling chamber and a cooling load lock module respectively perform a first stage cooling and a second stage cooling on the aluminum nitride coated substrate in vacuum environments, so as to prevent the aluminum nitride coated substrate with the high temperature from being exposed in an atmosphere environment to generate the surface oxide. The method and device for decreasing the generation of the surface oxide of the aluminum nitride can further eliminate crystal defects caused by that gallium nitride is deposited on the surface oxide of the aluminum nitride in the next process.

The present disclosure describes a semiconductor structure and a method for forming the same. The semiconductor structure can include a substrate, first and second fin structures formed over the substrate, and an isolation structure between the first and second fin structures. The isolation structure can include a lower portion and an upper portion. The lower portion of the isolation structure can include a metal-free dielectric material. The upper portion of the isolation structure can include a metallic element and silicon.

The present disclosure is directed to method for the fabrication of spacer structures between source/drain (S/D) epitaxial structures and metal gate structures in nanostructure transistors. The method includes forming a fin structure with alternating first and second nanostructure elements on a substrate. The method also includes etching edge portions of the first nanostructure elements in the fin structure to form cavities. Further, depositing a spacer material on the fin structure to fill the cavities and removing a portion of the spacer material in the cavities to form an opening in the spacer material. In addition, the method includes forming S/D epitaxial structures on the substrate to abut the fin structure and the spacer material so that sidewall portions of the S/D epitaxial structures seal the opening in the spacer material to form an air gap in the spacer 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.

In an embodiment, a method includes: forming a gate dielectric layer on an interface layer; forming a doping layer on the gate dielectric layer, the doping layer including a dipole-inducing element; annealing the doping layer to drive the dipole-inducing element through the gate dielectric layer to a first side of the gate dielectric layer adjacent the interface layer; removing the doping layer; forming a sacrificial layer on the gate dielectric layer, a material of the sacrificial layer reacting with residual dipole-inducing elements at a second side of the gate dielectric layer adjacent the sacrificial layer; removing the sacrificial layer; forming a capping layer on the gate dielectric layer; and forming a gate electrode layer on the capping layer.

Disclosed are a low-temperature polycrystalline silicon thin film transistor (LTPS TFT), a method for fabricating the same, an array substrate, a display panel, and a display device. The LTPS TFT includes an active layer, a source, a drain, a gate, and a gate insulating layer which are arranged on a substrate. The gate insulating layer is arranged between the active layer and the gate, and a graphene oxide layer which is arranged between the active layer and the gate insulating layer. Since the graphene oxide layer is arranged between the active layer and the gate insulating layer, the interface between the active layer and the gate insulating layer of polycrystalline (P-Si) has a reduced roughness and interfacial defect density, and a pre-cleaning process is not necessary for the gate insulating layer.

The present invention relates to a method for manufacturing a laterally insulated-gate bipolar transistor, comprising: providing a wafer having an N-type buried layer (10), an STI (40), and a first N well (22)/a first P well (24) which are formed successively from above a substrate; depositing and forming a high-temperature oxide film on the first N well (22) of the wafer; performing thermal drive-in on the wafer and performing photoetching and etching on the high-temperature oxide film to form a mini oxide layer (60); performing photoetching and ion implantation so as to form a second N well (32) inside the first N well (22) and second P wells (34) inside the first N well (22) and the first P well (24); then successively forming a gate oxide layer and a polysilicon gate (72), wherein one end of the gate oxide layer and the polysilicon gate (72) extends onto the second P well (34) inside the first N well (22), and the other end extends onto the mini oxide layer (60) on the second N well (32); and photoetching and injecting N-type ions between the mini oxide layer (60) and the STI (40) adjacent to the mini oxide layer (60) to form a drain electrode, and at the same time forming a source electrode (51) inside the second P well (34).

A method of manufacturing a semiconductor device includes forming a thin film having excellent etching resistance and a low dielectric constant on a substrate, removing first impurities containing H.sub.2O and Cl from the thin film by heating the thin film at a first temperature higher than a temperature of the substrate in the forming of the thin film, and removing second impurities containing a hydrocarbon compound (C.sub.xH.sub.y-based impurities) from the thin film in which heat treatment is performed at the first temperature by heating the thin film at a second temperature equal to or higher than the first temperature.