Abstract: A method for forming an ultra shallow junction on a substrate is provided. In certain embodiments a method of forming an ultra shallow junction on a substrate is provided. The substrate is placed into a process chamber. A silicon carbon layer is deposited on the substrate. The silicon carbon layer is exposed to a dopant. The substrate is heated to a temperature greater than 950° C. so as to cause substantial annealing of the dopant within the silicon carbon layer. In certain embodiments the substrate is heated to a temperature between about 1000° C. and about 1100°. In certain embodiments the substrate is heated to a temperature between about 1030° C. and 1050° C. In certain embodiments, a structure having an abrupt p-n junction is provided.

Abstract: Methods are disclosed for adjusting the temperature of at least a portion of the surface of a reaction chamber during a film formation process to control film properties. More than one portion of the chamber surface may be temperature-modulated, and may be accomplished by actively keeping the temperature of a first wall of the reaction chamber above the temperature of a second wall during the film formation process.

Abstract: Embodiments of methods for depositing silicon germanium (SiGe) layers on a substrate are disclosed herein. In some embodiments, the method includes depositing a silicon germanium seed layer atop the substrate using a first precursor comprising silicon and chlorine; and depositing a silicon germanium bulk layer atop the silicon germanium seed layer using a second precursor comprising silicon and hydrogen. In some embodiments, the first silicon precursor gas may comprise at least one of dichlorosilane (H2SiCl2), trichlorosilane (HSiCl3), or silicon tetrachloride (SiCl4). In some embodiments, the second silicon precursor gas may comprise at least one of silane (SiH4), or disilane (Si2H6).

Abstract: Methods and apparatus are disclosed for the formation and utilization of metastable specie in a reaction chamber for processing substrates. The metastable specie may be used for etching the surface of substrates in situ, deposition processes during processing of the substrate.

Abstract: Methods and apparatus for processing a substrate are provided herein. In some embodiments, a method of processing a substrate may include providing a substrate having at least one of a defect or a contaminant disposed on or near a surface of the substrate; and selectively annealing a portion of the substrate with a laser beam in the presence of a process gas comprising hydrogen. The laser beam may be moved over the substrate or continuously, or in a stepwise fashion. The laser beam may be applied in a continuous wave or pulsed mode. The process gas may further comprise an inert gas, such as, at least one of helium, argon, or nitrogen. A layer of material may be subsequently deposited atop the annealed substrate.

Abstract: Systems and apparatus are disclosed for adjusting the temperature of at least a portion of the surface of a reaction chamber during a film formation process to control film properties. More than one portion of the chamber surface may be temperature-modulated.

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 providing constant emissivity of the backside of susceptors are provided. Provided is a susceptor comprising: a susceptor plate having a surface for supporting a wafer and a backside surface opposite the wafer supporting surface; a layer comprising an oxide, a nitride, an oxynitride, or combinations thereof located on the backside surface of the susceptor plate, the layer being stable in the presence of a reactive process gas. The layer comprises, for example, silicon dioxide, silicon nitride, silicon oxynitride, or combinations thereof. Also provided is a method comprising: providing a susceptor in a deposition chamber, the susceptor comprising a susceptor plate and a layer comprising an oxide, a nitride, an oxynitride, or combinations thereof, the layer being stable in the presence of the reactive process gases; locating the wafer on a support surface of the susceptor plate.

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 are disclosed for the formation of vaporizing liquid precursor materials. The methods or apparatus can be used as part of a chemical vapor deposition apparatus or system, for example for forming films on substrates. The methods and apparatus involve providing a vessel for containing a liquid precursor and diffusing element having external cross-section dimensions substantially equal to the internal cross-sectional dimensions of the vessel.

Abstract: A method for forming an ultra shallow junction on a substrate is provided. In certain embodiments a method of forming an ultra shallow junction on a substrate is provided. The substrate is placed into a process chamber. A silicon carbon layer is deposited on the substrate. The silicon carbon layer is exposed to a dopant. The substrate is heated to a temperature greater than 950° C. so as to cause substantial annealing of the dopant within the silicon carbon layer. In certain embodiments the substrate is heated to a temperature between about 1000° C. and about 1100°. In certain embodiments the substrate is heated to a temperature between about 1030° C. and 1050° C. In certain embodiments, a structure having an abrupt p-n junction is provided.

Abstract: Methods and apparatus are disclosed for the formation and utilization of metastable specie in a reaction chamber for processing substrates. The metastable specie may be used for etching the surface of substrates in situ, deposition processes during processing of 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, systems and apparatus are disclosed for adjusting the temperature of at least a portion of the surface of a reaction chamber during a film formation process to control film properties. More than one portion of the chamber surface may be temperature-modulated.

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 bi-layer silicon electrode and its method of fabrication is described. The electrode of the present invention comprises a lower polysilicon film having a random grain microstructure, and an upper polysilicon film having a columnar grain microstructure.

Abstract: Embodiments of the invention generally provide a method for depositing a film containing silicon (Si) and nitrogen (N). In one embodiment, the method includes heating a substrate disposed in a processing chamber to a temperature less than about 650 degrees Celsius, flowing a nitrogen-containing gas into the processing chamber, flowing a silicon-containing gas into the processing chamber, and depositing a SiN-containing layer on a substrate. The silicon-containing gas is at least one of a gas identified as NR2—Si(R?2)—Si(R?2)—NR2 (amino(di)silanes), R3—Si—N?N?N (silyl azides), R?3—Si—NR—NR2 (silyl hydrazines) or 1,3,4,5,7,8-hexamethytetrasiliazane, wherein R and R? comprise at least one functional group selected from the group of a halogen, an organic group having one or more double bonds, an organic group having one or more triple bonds, an aliphatic alkyl group, a cyclical alkyl group, an aromatic group, an organosilicon group, an alkyamino group, or a cyclic group containing N or Si.

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 of forming a polycrystalline silicon film comprising: providing a process gas mix comprising a silicon source gas and a dilution gas mix wherein the dilution gas mix comprises H2 and an inert gas; and forming a polycrystalline silicon film from said silicon source gas.

Abstract: A method for depositing doped polycrystalline or amorphous silicon film. The method includes placing a substrate onto a susceptor. The susceptor includes a body having a resistive heater therein and a thermocouple in physical contact with the resistive heater. The susceptor is located in the process chamber such that the process chamber has a top portion above the susceptor and a bottom portion below the susceptor. The method further includes heating the susceptor. The method further includes providing a process gas mix into the process chamber through a shower head located on the susceptor. The process gas mix includes a silicon source gas, a dopant gas, and a carrier gas. The carrier gas includes nitrogen. The method further includes forming the doped silicon film from the silicon source gas.