Patent application number | Description | Published |
20090026496 | METHODS OF MAKING SUBSTITUTIONALLY CARBON-DOPED CRYSTALLINE SI-CONTAINING MATERIALS BY CHEMICAL VAPOR DEPOSITION - Methods of making Si-containing films that contain relatively high levels of substitutional dopants involve chemical vapor deposition using trisilane and a dopant precursor. Extremely high levels of substitutional incorporation may be obtained, including crystalline silicon films that contain 2.4 atomic % or greater substitutional carbon. Substitutionally doped Si-containing films may be selectively deposited onto the crystalline surfaces of mixed substrates by introducing an etchant gas during deposition. | 01-29-2009 |
20090111246 | INHIBITORS FOR SELECTIVE DEPOSITION OF SILICON CONTAINING FILMS - A method for depositing a single crystalline silicon film comprises: providing a substrate disposed within a chamber; introducing to the chamber under chemical vapor deposition conditions a silicon precursor, a chlorine-containing etchant and an inhibitor source for decelerating reactions between the silicon precursor and the chlorine-containing etchant; and selectively depositing a doped crystalline Si-containing film onto the substrate. | 04-30-2009 |
20090163001 | SEPARATE INJECTION OF REACTIVE SPECIES IN SELECTIVE FORMATION OF FILMS - Methods and apparatuses for selective epitaxial formation of films separately inject reactive species into a CVD chamber. The methods are particularly useful for selective deposition using volatile combinations of precursors and etchants. Formation processes include simultaneous supply of precursors and etchants for selective deposition, or sequential supply for cyclical blanket deposition and selective etching. In either case, precursors and etchants are provided along separate flow paths that intersect in the relatively open reaction space, rather than in more confined upstream locations. | 06-25-2009 |
20090189185 | EPITAXIAL GROWTH OF RELAXED SILICON GERMANIUM LAYERS - A relaxed silicon germanium structure comprises a silicon buffer layer produced using a chemical vapor deposition process with an operational pressure greater than approximately 1 torr. The relaxed silicon germanium structure further comprises a silicon germanium layer deposited over the silicon buffer layer. The silicon germanium layer has less than about 10 threading dislocations per square centimeter. By depositing the silicon buffer layer at a reduced deposition rate, the overlying silicon germanium layer can be provided with a “crosshatch free” surface. | 07-30-2009 |
20100093159 | SEPARATE INJECTION OF REACTIVE SPECIES IN SELECTIVE FORMATION OF FILMS - Methods and apparatuses for selective epitaxial formation of films separately inject reactive species into a CVD chamber. The methods are particularly useful for selective deposition using volatile combinations of precursors and etchants. Formation processes include simultaneous supply of precursors and etchants for selective deposition, or sequential supply for cyclical blanket deposition and selective etching. In either case, precursors and etchants are provided along separate flow paths that intersect in the relatively open reaction space, rather than in more confined upstream locations. | 04-15-2010 |
20100140744 | METHODS OF DEPOSITING ELECTRICALLY ACTIVE DOPED CRYSTALLINE SI-CONTAINING FILMS - Methods of making Si-containing films that contain relatively high levels of Group III or Group V dopants involve chemical vapor deposition using trisilane and a dopant precursor. Extremely high levels of substitutional incorporation may be obtained, including crystalline silicon films that contain at least about 3×10 | 06-10-2010 |
20110117732 | CYCLICAL EPITAXIAL DEPOSITION AND ETCH - Methods for selectively depositing high quality epitaxial material include introducing pulses of a silicon-source containing vapor while maintaining a continuous etchant flow. Epitaxial material is deposited on areas of a substrate, such as source and drain recesses. Between pulses, the etchant flow continues such that lower quality epitaxial material may be removed, as well as any non-epitaxial material that may have been deposited. The pulse of silicon-source containing vapor may be repeated until a desired thickness of epitaxial material is selectively achieved in semiconductor windows, such as recessed source/drain regions. | 05-19-2011 |
20120244688 | SELECTIVE EPITAXIAL FORMATION OF SEMICONDUCTIVE FILMS - Epitaxial layers are selectively formed in semiconductor windows by a cyclical process of repeated blanket deposition and selective etching. The blanket deposition phases leave non-epitaxial material over insulating regions, such as field oxide, and the selective etch phases preferentially remove non-epitaxial material while deposited epitaxial material builds up cycle-by-cycle. Quality of the epitaxial material improves relative to selective processes where no deposition occurs on insulators. Use of a germanium catalyst during the etch phases of the process aid etch rates and facilitate economical maintenance of isothermal and/or isobaric conditions throughout the cycles. Throughput and quality are improved by use of trisilane, formation of amorphous material over the insulating regions and minimizing the thickness ratio of amorphous:epitaxial material in each deposition phase. | 09-27-2012 |
20130029496 | Methods and Apparatus for a Gas Panel with Constant Gas Flow - A gas panel according to various aspects of the present invention is configured to deliver a constant flow rate of gases to a reaction chamber during a deposition process step. In one embodiment, the gas panel comprises a deposition sub-panel having a deposition injection line, a deposition vent line, and at least one deposition process gas line. The deposition injection line supplies a mass flow rate of a carrier gas to a reactor chamber. Each deposition process gas line may include a pair of switching valves that are configured to selectively direct a deposition process gas to the reactor chamber or a vent line. The deposition vent line also includes a switching valve configured to selectively direct a second mass flow rate of the carrier gas that is equal to the sum of the mass flow rate for all of the deposition process gases to the reactor chamber or a vent line. The gas panel is configured to substitute the mass flow rate of the deposition vent line with the mass flow rate of the deposition process lines, such that when the deposition vent line is directed to the reactor chamber the deposition process lines are directed to the vent line and when the deposition vent line is directed to the vent line the deposition process lines are directed to the reactor chamber. The substitution of the two mass flow rates maintains a constant mass flow rate of gases to the reactor chamber throughout the deposition process step. | 01-31-2013 |
20140209177 | METHODS AND APPARATUS FOR A GAS PANEL WITH CONSTANT GAS FLOW - A gas panel according to various aspects of the present invention is configured to deliver a constant flow rate of gases to a reaction chamber during a deposition process step. In one embodiment, the gas panel comprises a deposition sub-panel having a deposition injection line, a deposition vent line, and at least one deposition process gas line. The deposition injection line supplies a mass flow rate of a carrier gas to a reactor chamber. Each deposition process gas line may include a pair of switching valves that are configured to selectively direct a deposition process gas to the reactor chamber or a vent line. The deposition vent line also includes a switching valve configured to selectively direct a second mass flow rate of the carrier gas that is equal to the sum of the mass flow rate for all of the deposition process gases to the reactor chamber or a vent line. The gas panel is configured to substitute the mass flow rate of the deposition vent line with the mass flow rate of the deposition process lines, such that when the deposition vent line is directed to the reactor chamber the deposition process lines are directed to the vent line and when the deposition vent line is directed to the vent line the deposition process lines are directed to the reactor chamber. The substitution of the two mass flow rates maintains a constant mass flow rate of gases to the reactor chamber throughout the deposition process step. | 07-31-2014 |