Abstract: In one embodiment, a method for forming a silicon-based material on a substrate having dielectric materials and source/drain regions thereon within a process chamber is provided which includes exposing the substrate to a first process gas comprising silane, methylsilane, a first etchant, and hydrogen gas to deposit a first silicon-containing layer thereon. The first silicon-containing layer may be selectively deposited on the source/drain regions of the substrate while the first silicon-containing layer may be etched away on the surface of the dielectric materials of the substrate. Subsequently, the process further provides exposing the substrate to a second process gas comprising dichlorosilane and a second etchant to deposit a second silicon-containing layer selectively over the surface of the first silicon-containing layer on the substrate.

Abstract: In a first aspect, a method of forming an epitaxial film on a substrate is provided. The method includes (a) providing a substrate; (b) exposing the substrate to a silicon source and a carbon source so as to form a carbon-containing silicon epitaxial film; (c) encapsulating the carbon-containing silicon epitaxial film with an encapsulating film; and (d) exposing the substrate to Cl2 so as to etch the encapsulating film. Numerous other aspects are provided.

Abstract: The present invention has various aspects relating to the maximization of current carrying capacity of wafer level packaged chip scale solder pad mounted integrated circuits. In one aspect, the solder pad areas are maximized by using rectangular solder pads spaced as close together as reliable mounting to a circuit board will allow. In another aspect, multiple contact pads may be used for increasing the current capacity without using contact pads of different areas. In still another aspect, vias are used to directly connect one lead of high current component or components to a contact pad directly above that component, and to route a second lead of the high current component to an adjacent contact pad by way of a thick metal interconnect layer.

Abstract: In a first aspect, a first method of forming an epitaxial film on a substrate is provided. The first method includes (a) providing a substrate; (b) exposing the substrate to at least a silicon source so as to form an epitaxial film on at least a portion of the substrate; and (c) exposing the substrate to HCl and Cl2 so as to etch the epitaxial film and any other films formed during step (b). Numerous other aspects are provided.

Abstract: The present invention provides methods, systems, and apparatus for epitaxial film formation that includes an epitaxial chamber adapted to form an epitaxial layer on a substrate; a deposition gas manifold adapted to supply at least one deposition gas and a carrier gas to the epitaxial chamber; and an etchant gas manifold, separate from the deposition gas manifold, and adapted to supply at least one etchant gas and a carrier gas to the epitaxial chamber. Numerous other aspects are disclosed.

Abstract: The present invention provides systems and methods of forming an epitaxial film on a substrate. After heating in a process chamber, the substrate is exposed to a silicon source and at least one of SiH2(CH3)2, SiH(CH3)3, Si(CH3)4, 1,3-disilabutane, and C2H2, at a temperature of greater than about 250 degrees Celsius and a pressure greater than about 1 Torr so as to form an epitaxial film on at least a portion of the substrate. Then, the substrate is exposed to an etchant so as to etch the epitaxial film and any other films formed during the deposition. The deposition and etching may be repeated until a film of a desired thickness is achieved. Numerous other aspects are disclosed.

Abstract: In one example, a method of epitaxially forming a silicon-containing material on a substrate surface is presented which includes positioning a substrate into a process chamber. The substrate has a monocrystalline surface and at least a second surface, such as an amorphous surface and/or a polycrystalline surface. The substrate is exposed to a deposition gas to deposit an epitaxial layer on the monocrystalline surface and a polycrystalline layer on the second surface. The deposition gas preferably contains a silicon source and at least a second elemental source, such as a germanium source, a carbon source and/or combinations thereof. Thereafter, the method further provides exposing the substrate to an etchant gas to etch the polycrystalline layer and the epitaxial layer in a manner such that the polycrystalline layer is etched at a faster rate than the epitaxial layer.

Abstract: In one example, a method of epitaxially forming a silicon-containing material on a substrate surface is presented which includes positioning a substrate into a process chamber. The substrate has a monocrystalline surface and at least a second surface, such as an amorphous surface and/or a polycrystalline surface. The substrate is exposed to a deposition gas to deposit an epitaxial layer on the monocrystalline surface and a polycrystalline layer on the second surface. The deposition gas preferably contains a silicon source and at least a second elemental source, such as a germanium source, a carbon source and/or combinations thereof. Thereafter, the method further provides exposing the substrate to an etchant gas to etch the polycrystalline layer and the epitaxial layer in a manner such that the polycrystalline layer is etched at a faster rate than the epitaxial layer.

Abstract: The invention generally teaches a method for depositing a silicon film or silicon germanium film on a substrate comprising placing the substrate within a process chamber and heating the substrate surface to a temperature in the range from about 600° C. to about 900° C. while maintaining a pressure in the range from about 0.1 Torr to about 200 Torr. A deposition gas is provided to the process chamber and includes SiH4, an optional germanium source gas, an etchant, a carrier gas and optionally at least one dopant gas. The silicon film or the silicon germanium film is selectively and epitaxially grown on the substrate. One embodiment teaches a method for depositing a silicon-containing film with an inert gas as the carrier gas. Methods may include the fabrication of electronic devices utilizing selective silicon germanium epitaxial films.

Abstract: In one embodiment, a method for forming a silicon-based material on a substrate having dielectric materials and source/drain regions thereon within a process chamber is provided which includes exposing the substrate to a first process gas comprising silane, methylsilane, a first etchant, and hydrogen gas to deposit a first silicon-containing layer thereon. The first silicon-containing layer may be selectively deposited on the source/drain regions of the substrate while the first silicon-containing layer may be etched away on the surface of the dielectric materials of the substrate. Subsequently, the process further provides exposing the substrate to a second process gas comprising dichlorosilane and a second etchant to deposit a second silicon-containing layer selectively over the surface of the first silicon-containing layer on the substrate.

Abstract: In one embodiment, a method for forming a silicon-based material on a substrate having dielectric materials and source/drain regions thereon within a process chamber is provided which includes exposing the substrate to a first process gas comprising silane, methylsilane, a first etchant, and hydrogen gas to deposit a first silicon-containing layer thereon. The first silicon-containing layer may be selectively deposited on the source/drain regions of the substrate while the first silicon-containing layer may be etched away on the surface of the dielectric materials of the substrate. Subsequently, the process further provides exposing the substrate to a second process gas comprising dichlorosilane and a second etchant to deposit a second silicon-containing layer selectively over the surface of the first silicon-containing layer on the substrate.

Abstract: Methods and apparatus for formation and treatment of epitaxial layers containing silicon and carbon are disclosed. Treatment of the epitaxial layer converts interstitial carbon to substitutional carbon. Specific embodiments pertain to the formation and treatment of epitaxial layers in semiconductor devices, for example, Metal Oxide Semiconductor Field Effect Transistor (MOSFET) devices. In specific embodiments, the treatment of the epitaxial layer involves annealing for short periods of time, for example, by laser annealing, millisecond annealing, rapid thermal annealing, and spike annealing in a environment containing nitrogen.

Abstract: In one example, a method of epitaxially forming a silicon-containing material on a substrate surface is presented which includes positioning a substrate into a process chamber. The substrate has a monocrystalline surface and at least a second surface, such as an amorphous surface and/or a polycrystalline surface. The substrate is exposed to a deposition gas to deposit an epitaxial layer on the monocrystalline surface and a polycrystalline layer on the second surface. The deposition gas preferably contains a silicon source and at least a second elemental source, such as a germanium source, a carbon source and/or combinations thereof. Thereafter, the method further provides exposing the substrate to an etchant gas to etch the polycrystalline layer and the epitaxial layer in a manner such that the polycrystalline layer is etched at a faster rate than the epitaxial layer.

Abstract: In one embodiment of the invention, a method for finishing or treating a silicon-containing surface is provided which includes removing contaminants and/or smoothing the surface contained on the surface by a slow etch process (e.g., about <100 ?/min). The silicon-containing surface is exposed to an etching gas that contains an etchant, a silicon source and a carrier gas. Preferably, the etchant is chlorine gas so that a relatively low temperature (e.g., <800° C.) is used during etching or smoothing processes. In another embodiment of the invention, a method for etching a silicon-containing surface during a fast etch process (e.g., about >100 ?/min) is provided which includes removing silicon-containing material to form a recess in a source/drain (S/D) area on the substrate. The silicon-containing surface is exposed to an etching gas that contains an etchant, preferably chlorine, a carrier gas and an optional silicon source.

Abstract: The invention generally teaches a method for depositing a silicon film or silicon germanium film on a substrate comprising placing the substrate within a process chamber and heating the substrate surface to a temperature in the range from about 600° C. to about 900° C. while maintaining a pressure in the range from about 0.1 Torr to about 200 Torr. A deposition gas is provided to the process chamber and includes SiH4, an optional germanium source gas, an etchant, a carrier gas and optionally at least one dopant gas. The silicon film or the silicon germanium film is selectively and epitaxially grown on the substrate. One embodiment teaches a method for depositing a silicon-containing film with an inert gas as the carrier gas. Methods may include the fabrication of electronic devices utilizing selective silicon germanium epitaxial films.

Abstract: In one embodiment, a method for fabricating a silicon-based device on a substrate surface is provided which includes depositing a first silicon-containing layer by exposing the substrate surface to a first process gas comprising Cl2SiH2, a germanium source, a first etchant and a carrier gas and depositing a second silicon-containing layer by exposing the first silicon-containing layer to a second process gas comprising SiH4 and a second etchant. In another embodiment, a method for depositing a silicon-containing material on a substrate surface is provided which includes depositing a first silicon-containing layer on the substrate surface with a first germanium concentration of about 15 at % or more.

Abstract: A method implemented by one or more processors, including receiving first information relating a plurality of flow rates of a species to corresponding concentrations of the species within films generated using the flow rates; receiving a desired concentration profile of the species within a desired film; and generating a plurality of process steps that, when performed, would form the desired film with the desired concentration profile by controlling the flow rate of the species based, in part, on the first information and the desired concentration profile, wherein a first concentration of the species at a first point in the desired concentration profile differs from a second concentration of the species at a second point in the desired concentration profile. A computer-readable medium, system and apparatus are also disclosed.

Abstract: A waveguide structure and method of fabricating the same, the method comprising forming a first graded layer on a substrate, wherein the first graded layer comprises a first and a second optical material, and a lattice constant adjusting material, wherein the concentration of the second optical material increases with the height of the first graded layer and the concentration of the lattice constant adjusting material varies in proportion to the second optical material; and forming a second graded layer, the second graded layer comprising the first and second optical materials, and a lattice constant adjusting material, wherein the concentration of the second optical material decreases with the height of the second graded layer and the concentration of the lattice constant adjusting material varies in proportion to the second optical material.

Abstract: A method is provided wherein a temperature reading error of a pyrometer is avoided. An upper pyrometer is used to detect infrared radiation from a test layer formed on a test substrate under standard processing conditions. The infrared radiation from the test layer has a period having a length which is indicative of growth rate of the layer. The period is generally inversely proportional to the growth rate. The growth rate is directly related to the temperature.

Abstract: A method of forming a planar waveguide structure, comprising forming a first graded layer on a substrate, wherein the first graded layer comprises a first and a second optical material, wherein the concentration of the first optical material increases with the height of the first graded layer; forming a second graded layer on the first graded layer, the second graded layer comprising the first and second optical materials wherein the concentration of the first optical material decreases with the height of the second graded layer. The method further including forming a uniform layer on the first graded layer, the uniform layer containing first and second optical materials wherein the first optical material concentration is constant.