19561 results about "Silanes" patented technology

A method and apparatus for depositing a low dielectric constant film by reaction of an organo silane compound and an oxidizing gas. The oxidized organo silane film has excellent barrier properties for use as a liner or cap layer adjacent other dielectric layers. The oxidized organo silane film can also be used as an etch stop or an intermetal dielectric layer for fabricating dual damascene structures. The oxidized organo silane films also provide excellent adhesion between different dielectric layers. A preferred oxidized organo silane film is produced by reaction of methyl silane, CH3SiH3, and N2O.

Methods of producing metal-containing thin films with low impurity contents on a substrate by atomic layer deposition (ALD) are provided. The methods preferably comprise contacting a substrate with alternating and sequential pulses of a metal source chemical, a second source chemical and a deposition enhancing agent. The deposition enhancing agent is preferably selected from the group consisting of hydrocarbons, hydrogen, hydrogen plasma, hydrogen radicals, silanes, germanium compounds, nitrogen compounds, and boron compounds. In some embodiments, the deposition-enhancing agent reacts with halide contaminants in the growing thin film, improving film properties.

Classes of liquid aminosilanes have been found which allow for the production of silicon carbo-nitride films of the general formula SixCyNz. These aminosilanes, in contrast, to some of the precursors employed heretofore, are liquid at room temperature and pressure allowing for convenient handling. In addition, the invention relates to a process for producing such films. The classes of compounds are generally represented by the formulas: and mixtures thereof, wherein R and R1 in the formulas represent aliphatic groups typically having from 2 to about 10 carbon atoms, e.g., alkyl, cycloalkyl with R and R1 in formula A also being combinable into a cyclic group, and R2 representing a single bond, (CH2)n, a ring, or SiH2.

In one embodiment, a method for depositing a conductive material on a substrate is provided which includes exposing a substrate containing a barrier layer to a volatile reducing precursor to form a reducing layer during a soak process, exposing the reducing layer to a catalytic-metal precursor to deposit a catalytic metal-containing layer on the barrier layer, and depositing a conductive layer (e.g., copper) on the catalytic metal-containing layer. The volatile reducing precursor may include phosphine, diborane, silane, a plasma thereof, or a combination thereof and be exposed to the substrate for a time period within a range from about 1 second to about 30 seconds during the soak process. The catalytic metal-containing layer may contain ruthenium, cobalt, rhodium, iridium, nickel, palladium, platinum, silver, or copper. In one example, the catalytic metal-containing layer is deposited by a vapor deposition process utilizing ruthenium tetroxide formed by an in situ process.

A method of filling a recess with an insulation film includes: introducing an alkoxysilane or aminosilane precursor containing neither a Si—C bond nor a C—C bond into a reaction chamber where a substrate having an irregular surface including a recess is placed; and depositing a flowable Si-containing insulation film on the irregular surface of the substrate to fill the recess therewith by plasma reaction at −50° C. to 100° C.

Described herein are precursors and methods for forming silicon-containing films. In one aspect, there is provided a precursor of Formula I:wherein R1 is selected from linear or branched C3 to C10 alkyl group, linear or branched C3 to C10 alkenyl group, linear or branched C3 to C10 alkynyl group, C1 to C6 dialkylamino group, electron withdrawing group, and C6 to C10 aryl group; R2 is selected from hydrogen, linear or branched C1 to C10 alkyl group, linear or branched C3 to C6 alkenyl group, linear or branched C3 to C6 alkynyl group, C1 to C6 dialkylamino group, C6 to C10 aryl group, linear or branched C1 to C6 fluorinated alkyl group, electron withdrawing group, and C4 to C10 aryl group; optionally wherein R1 and R2 are linked together to form ring selected from substituted or unsubstituted aromatic ring or substituted or unsubstituted aliphatic ring; and n=1 or 2.

Methods for forming silicon dioxide thin films on hydrophobic surfaces are provided. For example, in some embodiments, silicon dioxide films are deposited on porous, low-k materials. The silicon dioxide films can be deposited using a catalyst and a silanol. In some embodiments, an undersaturated dose of one or more of the reactants can be used in forming a pore-sealing layer over a porous material.

A method of operating a substrate processing chamber that includes, prior to a substrate processing operation, flowing a seasoning gas comprising silane and oxygen into said chamber at a flow ratio of greater than or equal to about 1.6:1 oxygen to silane to deposit a silicon oxide film over at least one aluminum nitride nozzle exposed to an interior portion of the chamber. Also, a substrate processing system that includes a housing, a gas delivery system for introducing a seasoning gas into a vacuum chamber, where the gas delivery system comprises one or more aluminum nitride nozzles exposed to the vacuum chamber, a controller and a memory having a program having instructions for controlling the gas delivery system to flow a seasoning gas that has an oxygen to silane ratio greater than or equal to about 1.6:1 to deposit a silicon oxide film on the aluminum nitride nozzles.

A method of operating a substrate processing chamber that includes, prior to a substrate processing operation, flowing a seasoning gas comprising silane and oxygen into said chamber at a flow ratio of greater than or equal to about 1.6:1 oxygen to silane to deposit a silicon oxide film over at least one aluminum nitride nozzle exposed to an interior portion of the chamber. Also, a substrate processing system that includes a housing, a gas delivery system for introducing a seasoning gas into a vacuum chamber, where the gas delivery system comprises one or more aluminum nitride nozzles exposed to the vacuum chamber, a controller and a memory having a program having instructions for controlling the gas delivery system to flow a seasoning gas that has an oxygen to silane ratio greater than or equal to about 1.6:1 to deposit a silicon oxide film on the aluminum nitride nozzles.

A CVD method for forming a silicon nitride film includes exhausting a process chamber (8) that accommodates a target substrate (W), and supplying a silane family gas (HCD) and ammonia gas (NH3) into the process chamber, thereby forming a silicon nitride film on the target substrate by CVD. Said forming a silicon nitride film on the target substrate alternately includes a first period of performing supply of the silane family gas (HCD) into the process chamber (8), and a second period of stopping supply of the silane family gas.

The negative effect of oxygen on some metal films can be reduced or prevented by contacting the films with a treatment agent comprising silane or borane. In some embodiments, one or more films in an NMOS gate stack are contacted with a treatment agent comprising silane or borane during or after deposition.

The present invention relates to a method of forming an insulating film in a semiconductor device. After a mixed gas of alkyl silane gas and N2O gas is supplied into the deposition equipment, a radio frequency power including a short pulse wave for causing incomplete reaction upon a gas phase reaction is applied to generate nano particle. The nano particle is then reacted to oxygen radical to form the insulating film including a plurality of nano voids. A low-dielectric insulating film that can be applied to the nano technology even in the existing LECVD equipment is formed.

This invention relates to an improved process for producing ternary metal silicon nitride films by the cyclic deposition of the precursors. The improvement resides in the use of a metal amide and a silicon source having both NH and SiH functionality as the precursors leading to the formation of such metal-SiN films. The precursors are applied sequentially via cyclic deposition onto the surface of a substrate. Exemplary silicon sources are monoalkylamino silanes and hydrazinosilanes represented by the formulas: (R1NH)nSiR2mH4-n-m (n=1,2; m=0,1,2; n+m=<3); and (R32N—NH)xSiR4yH4-x-y (x=1,2; y=0,1,2; x+y=<3) wherein in the above formula R1-4 are same or different and independently selected from the group consisting of alkyl, vinyl, allyl, phenyl, cyclic alkyl, fluoroalkyl, silylalkyls.

An insulating film is formed on a target substrate by CVD, in a process field to be selectively supplied with a first process gas containing a silane family gas, a second process gas containing a nitriding or oxynitriding gas, and a third process gas containing a carbon hydride gas. This method alternately includes first to fourth steps. The first step performs supply of the first and third process gases to the field while stopping supply of the second process gas to the process field. The second step stops supply of the first to third process gases to the field. The third step performs supply of the second process gas to the field while stopping supply of the first and third process gases to the field. The fourth step stops supply of the first to third process gases to the field.

A method for forming a strained silicon layer device with improved wafer throughput and low defect density including providing a silicon substrate; epitaxially growing a first silicon layer using at least one deposition precursor selected from the group consisting of disilane and trisilane; epitaxially growing a step-grade SiGe buffer layer over and contacting the first silicon layer using at least one deposition precursor selected from the group consisting of disilane and trisilane; epitaxially growing a SiGe capping layer over and contacting the step-grade SiGe buffer layer using at least one deposition precursor selected from the group consisting of disilane and trisilane; and, epitaxially growing a second silicon layer using at least one deposition precursor selected from the group consisting of disilane and silane.

A method of forming spacers for spacer-defined multiple pattering (SDMP), includes: depositing a pattern transfer film by PEALD on the entire patterned surface of a template using halogenated silane as a precursor and nitrogen as a reactant at a temperature of 200° C. or less, which pattern transfer film is a silicon nitride film; dry-etching the template using a fluorocarbon as an etchant, and thereby selectively removing a portion of the pattern transfer film formed on a top of a core material and a horizontal portion of the pattern transfer film while leaving the core material and a vertical portion of the pattern transfer film as a vertical spacer, wherein a top of the vertical spacer is substantially flat; and dry-etching the core material, whereby the template has a surface patterned by the vertical spacer on a underlying layer.

An impurity-doped silicon nitride or oxynitride film is formed on a target substrate by CVD, in a process field to be selectively supplied with a first process gas containing a silane family gas, a second process gas containing a nitriding or oxynitriding gas, and a third process gas containing a doping gas. This method alternately includes first to fourth steps. The first step performs supply of the first and third process gases to the field. The second step stops supply of the first to third process gases to the field. The third step performs supply of the second process gas to the field while stopping supply of the first and third process gases to the field, and includes an excitation period of exciting the second process gas by an exciting mechanism. The fourth step stops supply of the first to third process gases to the field.

The object of the present invention is to provide a carbon nanotube composition that does not impair the characteristics of the carbon nanotubes itself, allows the carbon nanotubes to be dispersed or solubilized in a solvent, does not cause separation or aggregation of the carbon nanotubes even during long-term storage, has superior electrical conductivity, film formability and moldability, can be easily coated or covered onto a base material, and the resulting coated film has superior moisture resistance, weather resistance and hardness; a composite having a coated film composed thereof; and, their production methods. In order to achieve this object, the present invention provides a carbon nanotube composition that contains a conducting polymer (a) or heterocyclic compound trimer (i), a solvent (b) and carbon nanotubes (c), and may additionally contain a high molecular weight compound (d), a basic compound (e), a surfactant (f), a silane coupling agent (g) and colloidal silica (h) as necessary; a composite having a coated film composed of the composition; and, their production methods.

At a frame 26 in a microwave plasma processing apparatus 100, numerous horizontal spray gas nozzles 27 formed therein injection holes A and numerous vertical gas nozzles 28 formed therein injection holes B are fixed. A first gas supply means 50 injects argon gas through the injection holes A into an area near each dielectric parts 31a. A second gas supply means 55 injects silane gas and hydrogen gas through the injection holes B into a position at which the gases do not become over-dissociated. The gases injected as described above are raised to plasma with a microwave transmitted through each dielectric parts 31a. Since the vertical gas nozzles 28 are mounted at positions at which they do not block the flow of plasma traveling toward a substrate G, ions and electrons do not collide with the vertical gas nozzles 28 readily.

A method of forming a sidewall spacer on a gate electrode of a metal oxide semiconductor device that includes striking a first plasma to form an oxide layer on a side of the gate electrode, where the first plasma is generated from a oxide gas that includes O3 and bis-(tertiarybutylamine)silane, and striking a second plasma to form a carbon-doped nitride layer on the oxide layer, where the second plasma may be generated from a nitride gas that includes NH3 and the bis-(tertiarybutylamine)silane. The first and second plasmas may be formed using plasma CVD and the bis-(tertiarybutylamine)silane flows uninterrupted between the striking of the first plasma and the striking of the second plasma.