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.

Embodiments of the present disclosure generally relate to processes for forming silicon- and boron-containing films for use in, e.g., spacer-defined patterning applications. In an embodiment, a spacer-defined patterning process is provided. The process includes disposing a substrate in a processing volume of a processing chamber, the substrate having patterned features formed thereon, and flowing a first process gas into the processing volume, the first process gas comprising a silicon-containing species, the silicon-containing species having a higher molecular weight than SiH.sub.4. The process further includes flowing a second process gas into the processing volume, the second process gas comprising a boron-containing species, and depositing, under deposition conditions, a conformal film on the patterned features, the conformal film comprising silicon and boron.

A liquid crystal display device with a high aperture ratio is provided. A liquid crystal display device with low power consumption is provided. A display device includes a transistor and a capacitor. The transistor includes a first insulating layer, a first semiconductor layer in contact with the first insulating layer, a second insulating layer in contact with the first semiconductor layer, and a first conductive layer electrically connected to the first semiconductor layer via an opening portion provided in the second insulating layer. The capacitor includes a second conductive layer in contact with the first insulating layer, the second insulating layer in contact with the second conductive layer, and the first conductive layer in contact with the second insulating layer. The second conductive layer includes a composition similar to that of the first semiconductor layer. The first conductive layer and the second conductive layer are configured to transmit visible light.

In an embodiment, a method includes: forming a differential contact etch stop layer (CESL) having a first portion over a source/drain region and a second portion along a gate stack, the source/drain region being in a substrate, the gate stack being over the substrate proximate the source/drain region, a first thickness of the first portion being greater than a second thickness of the second portion; depositing a first interlayer dielectric (ILD) over the differential CESL; forming a source/drain contact opening in the first ILD; forming a contact spacer along sidewalls of the source/drain contact opening; after forming the contact spacer, extending the source/drain contact opening through the differential CESL; and forming a first source/drain contact in the extended source/drain contact opening, the first source/drain contact physically and electrically coupling the source/drain region, the contact spacer physically separating the first source/drain contact from the first ILD.

There is provided technique including: forming film on substrate by performing cycle, predetermined number of times, including non-simultaneously performing: (a) supplying precursor gas and inert gas to the substrate; and (b) supplying reaction gas to the substrate, wherein in (a), at least one selected from the group of the precursor gas and the inert gas stored in first tank is supplied to the substrate, and at least one selected from the group of the precursor gas and the inert gas stored in second tank is supplied to the substrate, and concentration of the precursor gas in the first tank while at least one selected from the group of the precursor gas and the inert gas is stored in the first tank differs from that in the second tank while at least one selected from the group of the precursor gas and the inert gas is stored in the second tank.

A film forming method includes preparing a substrate having a first region in which a metal film or an oxide film of the metal film is exposed, and a second region in which an insulating film is exposed, supplying, to the substrate, an organic compound containing, in a head group, a triple bond between carbon atoms represented by Chemical Formula (1) described in the specification, causing the organic compound to be selectively adsorbed in the first region among the first region and the second region, and cleaving the triple bond in the first region and forming a hydrophobic film having a honeycomb structure of carbon atoms through polymerization.

Embodiments of the present disclosure provide methods and apparatus for forming a desired material layer on a substrate between, during, prior to or after a patterning process. In one embodiment, a method for forming a material layer on a substrate includes pulsing a first gas precursor onto a surface of a substrate, attaching a first element from the first gas precursor onto the surface of the substrate, maintaining a substrate temperature less than about 110 degrees Celsius, pulsing a second gas precursor onto the surface of the substrate, and attaching a second element from the second gas precursor to the first element on the surface of the substrate.

A method for depositing a silicon nitride film is provided. A silicon nitride film is deposited in a depression formed in a surface of a substrate from a bottom surface and a lateral surface by ALD toward a center of the depression in a lateral direction so as to narrow a space at the center of the depression. First nitrogen radicals are adsorbed into the depression immediately before a stage of filling the space at the center with the silicon nitride film deposited toward the center of the depression. A silicon-containing gas is adsorbed on the first nitrogen radical in the depression by physical adsorption. Second nitrogen radicals are supplied into the depression so as to release the silicon-containing gas from the first nitrogen radical and to cause the released silicon-containing gas to react with the second nitrogen radical, thereby depositing a silicon nitride film to fill the central space.

A method for selectively etching layers of a first material with respect to layers of a second material in a stack is provided. The layers of the first material are partially etched with respect to the layers of the second material. A deposition layer is selectively deposited on the stack, wherein portions of the deposition layer covering the layers of the second material are thicker than portions covering the layers of the first material, the selective depositing comprising providing a first reactant, purging some of the first reactant, wherein some undeposited first reactant is not purged, and providing a second reactant, wherein the undeposited first reactant combines with the second reactant and selectively deposits on the layers of the second material with respect to the layers of the first material. The layers of the first material are selectively etched with respect to the layers of the second material.

A method includes placing a semiconductor substrate in a deposition chamber, wherein the semiconductor substrate includes a trench, and performing an atomic layer deposition (ALD) process to deposit a dielectric material within the trench, including flowing a first precursor of the dielectric material into the deposition chamber as a gas phase; flowing a second precursor of the dielectric material into the deposition chamber as a gas phase; and controlling the pressure and temperature within the deposition chamber such that the second precursor condenses on surfaces within the trench as a liquid phase of the second precursor, wherein the liquid phase of the second precursor has capillarity.