Localized stresses can be modulated in a film deposited on a bowed semiconductor substrate by selectively and locally curing the film by ultraviolet (UV) radiation. A bowed semiconductor substrate can be asymmetrically bowed. A UV-curable film is deposited on the front side or the backside of the bowed semiconductor substrate. A mask is provided between the UV-curable film and a UV source, where openings in the mask are patterned to selectively define exposed regions and non-exposed regions of the UV-curable film. Exposed regions of the UV-curable film modulate localized stresses to mitigate bowing in the bowed semiconductor substrate.

A manufacturing method for insulation layer, a manufacturing method for array substrate and an array substrate are disclosed. Wherein, the manufacturing method for insulation layer comprises steps of: depositing an insulation layer on a substrate; exposing and developing the insulation layer in order to obtain the insulation layer having an opening; light curing the insulation layer having the opening; and performing a high-temperature annealing treatment to the insulation layer having the opening after being light cured. Adopting the manufacturing method for insulation layer of the present invention, a situation of deformation at the opening of the insulation layer can be reduced.

A substrate processing method according to an embodiment includes a processing liquid supply step and an UV irradiation step. In the processing liquid supply step, a processing liquid is supplied to a substrate. In the UV irradiation step, the substrate after the processing liquid supply step is irradiated with ultraviolet rays having a wavelength of 200 nm or less, so that the substrate after the processing liquid supply step is destaticized.

A method includes removing a first dummy gate structure to form a recess around a first nanostructure and a second nanostructure; depositing a sacrificial layer in the recess with a flowable chemical vapor deposition (CVD); and patterning the sacrificial layer to leave a portion of the sacrificial layer between the first nanostructure and the second nanostructure. The method further include depositing a first work function metal in first recess; removing the first work function metal and the portion of the sacrificial layer from the recess; depositing a second work function metal in the recess, wherein the second work function metal is of an opposite type than the first work function metal; and depositing a fill metal over the second work function metal in the recess.

A first layer is located over a substrate. The first layer includes a first dielectric component and a first conductive component. A first etching stop layer is located over the first dielectric component. A metal capping layer is located over the first conductive component. A second etching stop layer is located over the first etching stop layer and over the metal capping layer. A second layer is located over the second etching stop layer. The second layer includes a second dielectric component and a second conductive component. A third conductive component electrically interconnects the second conductive component to the first conductive component.

A warpage-reducing semiconductor structure includes a wafer. The wafer includes a front side and a back side. Numerous semiconductor elements are disposed at the front side. A silicon oxide layer is disposed at the back side. A UV-transparent silicon nitride layer covers and contacts the silicon oxide layer. The refractive index of the UV-transparent silicon nitride layer is between 1.55 and 2.10.

A method for etching silicon at cryogenic temperatures is provided. The method includes forming an inert layer from condensation of a noble gas at cryogenic temperatures on exposed surfaces such as the sidewalls of a feature to passivate the sidewalls prior to the etching process. The method further includes flowing a fluorine-containing precursor gas into the chamber to form a fluorine-containing layer on the inert layer. The method further includes exposing the fluorine-containing layer and the inert layer to an energy source to form a passivation layer on the exposed portions of the substrate and exposing the substrate to ions to etch the substrate.

In a variety of processes for forming electronic devices that use spin-on dielectric materials, properties of the spin-on dielectric materials can be enhanced by curing these materials using plasma doping. For example, hardness and Young's modulus can be increased for the cured material. Other properties may be enhanced. The plasma doping to cure the spin-on dielectric materials uses a mechanism that is a combination of plasma ion implant and high energy radiation associated with the species ionized. In addition, physical properties of the spin-on dielectric materials can be modified along a length of the spin-on dielectric materials by selection of an implant energy and dopant dose for the particular dopant used, corresponding to a selection variation with respect to length.

A planarization apparatus, including a chuck having a first surface and a second surface at two opposing sides thereof. The chuck includes a first zone extending along a periphery of the chuck, a second zone at an inner portion of the chuck, the second zone being surrounded by the first zone; and a flexure connecting the first zone with the second zone. The first zone includes a first member extending along the first surface from the flexure and a first ring land protruding from the first member adjacent to the flexure.

In a variety of processes for forming electronic devices that use spin-on dielectric materials, properties of the spin-on dielectric materials can be enhanced by curing these materials using plasma doping. For example, hardness and Young's modulus can be increased for the cured material. Other properties may be enhanced. The plasma doping to cure the spin-on dielectric materials uses a mechanism that is a combination of plasma ion implant and high energy radiation associated with the species ionized. In addition, physical properties of the spin-on dielectric materials can be modified along a length of the spin-on dielectric materials by selection of an implant energy and dopant dose for the particular dopant used, corresponding to a selection variation with respect to length.