A method for forming ultraviolet (UV) radiation responsive metal-oxide containing film is disclosed. The method may include, depositing an UV radiation responsive metal oxide-containing film over a substrate by, heating the substrate to a deposition temperature of less than 400° C., contacting the substrate with a first vapor phase reactant comprising a metal component, a hydrogen component, and a carbon component, and contacting the substrate with a second vapor phase reactant comprising an oxygen containing precursor, wherein regions of the UV radiation responsive metal oxide-containing film have a first etch rate after UV irradiation and regions of the UV radiation responsive metal oxide-containing film not irradiated with UV radiation have a second etch rate, wherein the second etch rate is different from the first etch rate.

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.

A chuck assembly for holding a plate comprises a member configured to hold the plate, the member including a flexible portion configured to have a central opening, and a first cavity formed by the flexible portion, wherein the plate is held by the flexible portion by reducing pressure in the first cavity, a light-transmitting member covering the central opening of the member, and a fluid path in communication with a second cavity defined by the member, the plate held by the member and the light-transmitting member for pressurizing the second cavity.

Semiconductor processing methods are described for forming UV-treated, low-κ dielectric films. The methods may include flowing deposition precursors into a substrate processing region of a semiconductor processing chamber. The deposition precursors may include a silicon-and-carbon-containing precursor. The methods may further include generating a deposition plasma from the deposition precursors within the substrate processing region, and depositing a silicon-and-carbon-containing material on the substrate from plasma effluents of the deposition plasma. The as-deposited silicon-and-carbon-containing material may be characterized by greater than or about 5% hydrocarbon groups. The methods may still further include exposing the deposited silicon-and-carbon-containing material to ultraviolet light. The exposed silicon-and-carbon-containing material may be characterized by less than or about 2% hydrocarbon groups.

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.

The present disclosure relates to a semiconductor device with tilted insulating layers and a method for fabricating the semiconductor device with the tilted insulating layers. The semiconductor device includes a substrate, two conductive pillars positioned above the substrate and extended along a vertical axis, a first set of tilted insulating layers parallel to each other and positioned between the two conductive pillars, and a second set of tilted insulating layers parallel to each other and positioned between the two conductive pillars. The first set of tilted insulating layers are extended along a first direction slanted with respect to the vertical axis, the second set of tilted insulating layers are extended along a second direction slanted with respect to the vertical axis, and the first direction and the second direction are crossed.

A semiconductor device and method of manufacture comprise forming a channel-less, porous low K material. The material may be formed using a silicon backbone precursor and a hydrocarbon precursor to form a matrix material. The material may then be cured to remove a porogen and help to collapse channels within the material. As such, the material may be formed with a scaling factor of less than or equal to about 1.8.

A method for depositing a silicon-containing film, the method comprising: placing a substrate comprising at least one surface feature into a flowable CVD reactor which is at a temperature of from about −20° C. to about 400° C.; introducing into the reactor at least one silicon-containing compound having at least one acetoxy group to at least partially react the at least one silicon-containing compound to form a flowable liquid oligomer wherein the flowable liquid oligomer forms a silicon oxide coating on the substrate and at least partially fills at least a portion of the at least one surface feature. Once cured, the silicon oxide coating has a low k and excellent mechanical properties.

A chemical vapor deposition method for producing a dielectric film, the method comprising: providing a substrate into a reaction chamber; introducing gaseous reagents into the reaction chamber wherein the gaseous reagents comprise a silicon precursor comprising an silicon compound having Formula I as defined herein and applying energy to the gaseous reagents in the reaction chamber to induce reaction of the gaseous reagents to deposit a film on the substrate. The film as deposited is suitable for its intended use without an optional additional cure step applied to the as-deposited film.

Embodiments disclosed herein relate to cluster tools for forming and filling trenches in a substrate with a flowable dielectric material. In one or more embodiments, a cluster tool for processing a substrate contains a load lock chamber, a first vacuum transfer chamber coupled to the load lock chamber, a second vacuum transfer chamber, a cooling station disposed between the first vacuum transfer chamber and the second vacuum transfer chamber, a factory interface coupled to the load lock chamber, a plurality of first processing chambers coupled to the first vacuum transfer chamber, wherein each of the first processing chambers is a deposition chamber capable of performing a flowable layer deposition, and a plurality of second processing chambers coupled to the second vacuum transfer chamber, wherein each of the second processing chambers is a plasma chamber capable of performing a plasma curing process.