Patent application number | Description | Published |
20100096273 | CU SURFACE PLASMA TREATMENT TO IMPROVE GAPFILL WINDOW - A method and apparatus for selectively controlling deposition rate of conductive material during an electroplating process. Dopants are predominantly incorporated into a conductive seed layer on field regions of a substrate prior to filling openings in the field regions by electroplating. A substrate is positioned in one or more processing chambers, and barrier and conductive seed layers formed. A dopant precursor is provided to the chamber and ionized, with or without voltage bias. The dopant predominantly incorporates into the conductive seed layer on the field regions. Electrical conductivity of the conductive seed layer on the field regions is reduced relative to that of the conductive seed layer in the openings, resulting in low initial deposition rate of metal on the field regions during electroplating, and little or no void formation in the metal deposited in the openings. | 04-22-2010 |
20100105203 | METHODS FOR REDUCING DAMAGE TO SUBSTRATE LAYERS IN DEPOSITION PROCESSES - Methods of processing a substrate are provided herein. In some embodiments, a method of processing a substrate may include providing a substrate to a process chamber comprising a dielectric layer having a feature formed therein. A barrier layer may be formed within the feature. A coating of a first conductive material may be formed atop the barrier layer. A seed layer of the first conductive material may be formed atop the coating. The feature may be filled with a second conductive material. In some embodiments, the seed layer may be formed while maintaining the substrate at a temperature of greater than about 40 degrees Celsius. | 04-29-2010 |
20100155223 | Electromagnet array in a sputter reactor - A multi-step process performed in a plasma sputter chamber including sputter deposition from the target and argon sputter etching of the substrate. The chamber includes a quadruple electromagnetic coil array coaxially arranged in a rectangular array about a chamber axis outside the sidewalls of a plasma sputter reactor in back of an RF coil within the chamber. The coil currents can be separately controlled to produce different magnetic field distributions, for example, between a sputter deposition mode in which the sputter target is powered to sputter target material onto a wafer and a sputter etch mode in which the RF coil supports the argon sputtering plasma. A TaN/Ta barrier is first sputter deposited with high target power and wafer bias. Argon etching is performed with even higher wafer bias. A flash step is applied with reduced target power and wafer bias. | 06-24-2010 |
20110315319 | PRE-CLEAN CHAMBER WITH REDUCED ION CURRENT - Apparatus for processing substrates are disclosed herein. In some embodiments, a substrate processing system may include a process chamber having a first volume to receive a plasma and a second volume for processing a substrate; a substrate support disposed in the second volume; and a plasma filter disposed in the process chamber between the first volume and the second volume such that a plasma formed in the first volume can only flow from the first volume to the second volume through the plasma filter. In some embodiments, the substrate processing system includes a process kit coupled to the process chamber, wherein the plasma filter is disposed in the process kit. | 12-29-2011 |
20120225558 | METHODS FOR CONTACT CLEAN - Methods and apparatus for removing oxide from a surface, the surface comprising at least one of silicon and germanium, are provided. The method and apparatus are particularly suitable for removing native oxide from a metal silicide layer of a contact structure. The method and apparatus advantageously integrate both the etch stop layer etching process and the native oxide removal process in a single chamber, thereby eliminating native oxide growth or other contaminates redeposit during the substrate transfer processes. Furthermore, the method and the apparatus also provides the improved three-step chemical reaction process to efficiently remove native oxide from the metal silicide layer without adversely altering the geometry of the contact structure and the critical dimension of the trenches or vias formed in the contact structure. | 09-06-2012 |
20120276740 | METHODS FOR PRECLEANING A SUBSTRATE PRIOR TO METAL SILICIDE FABRICATION PROCESS - Methods for precleaning native oxides or other contaminants from a surface of a substrate prior to forming a metal silicide layer on the substrate. In one embodiment, a method for removing native oxides from a substrate includes transferring a substrate having an oxide layer disposed thereon into a processing chamber, performing a pretreatment process on the substrate by supplying a pretreatment gas mixture into the processing chamber, performing an oxide removal process on the substrate by supplying a cleaning gas mixture into the processing chamber, wherein the cleaning gas mixture includes at least an ammonium gas and a nitrogen trifluoride, and performing a post treatment process on the cleaned substrate by supplying a post treatment gas mixture into the processing chamber | 11-01-2012 |
20130193108 | METHODS OF END POINT DETECTION FOR SUBSTRATE FABRICATION PROCESSES - Methods and substrate processing systems for analyzing an end point of a process are provided. By-products of the process are detected and monitored to determine the completion of various types of reaction processes within a substrate processing chamber. The methods provide real time process monitoring, thereby reducing the need to rigidly constrain other substrate processing parameters, increasing chamber cleaning efficiency, and/or increasing substrate processing throughput. | 08-01-2013 |
20130228933 | BEOL Interconnect With Carbon Nanotubes - An integrated circuit with BEOL interconnects may comprise: a substrate including a semiconductor device; a first layer of dielectric over the surface of the substrate, the first layer of dielectric including a filled via for making electrical contact to the semiconductor device; and a second layer of dielectric on the first layer of dielectric, the second layer of dielectric including a trench running perpendicular to the longitudinal axis of the filled via, the trench being filled with an interconnect line, the interconnect line comprising cross-linked carbon nanotubes and being physically and electrically connected to the filled via. Cross-linked CNTs are grown on catalyst particles on the bottom of the trench using growth conditions including a partial pressure of precursor gas greater than the transition partial pressure at which carbon nanotube growth transitions from a parallel carbon nanotube growth mode to a cross-linked carbon nanotube growth mode. | 09-05-2013 |
20130316533 | METHOD FOR REMOVING NATIVE OXIDE AND ASSOCIATED RESIDUE FROM A SUBSTRATE - Native oxides and associated residue are removed from surfaces of a substrate by sequentially performing two plasma cleaning processes on the substrate in a single processing chamber. The first plasma cleaning process removes native oxide formed on a substrate surface by generating a cleaning plasma from a mixture of ammonia (NH | 11-28-2013 |
20140295665 | METHOD FOR REMOVING NATIVE OXIDE AND ASSOCIATED RESIDUE FROM A SUBSTRATE - Native oxides and associated residue are removed from surfaces of a substrate by sequentially performing two plasma cleaning processes on the substrate in a single processing chamber. The first plasma cleaning process removes native oxide formed on a substrate surface by generating a cleaning plasma from a mixture of ammonia (NH | 10-02-2014 |
20150235844 | HERMETIC CVD-CAP WITH IMPROVED STEP COVERAGE IN HIGH ASPECT RATIO STRUCTURES - Implementations described herein generally relate to methods for forming dielectric films in high aspect ratio features. In one implementation, a method for forming a silicon oxide layer is provided. A silicon-containing precursor gas is flown into a processing chamber having a substrate having a high aspect ratio feature disposed therein. Then a high frequency plasma is applied to the silicon-containing precursor gas to deposit a silicon-containing layer over the surface of the high aspect ratio feature. The processing chamber is purged to remove by-products from the silicon-containing layer deposition process. An oxygen-containing precursor gas is flown into the processing chamber. A high frequency plasma and a low frequency plasma are applied to the oxygen-containing precursor gas to form the silicon oxide layer. | 08-20-2015 |
20150331337 | ELECTROSTATIC CARRIER FOR HANDLING SUBSTRATES FOR PROCESSING - An electrostatic carrier is described for carrying a substrate for handling through different processes. The carrier has a dielectric plate having a top side and a bottom side and configured to be attached on a top side of the plate to a substrate using electrostatic force, and a base plate coupled to a bottom side of the dielectric plate. Electrodes are formed on the base plate and extend across the base plate parallel to the top side of the dielectric plate. The electrodes are configured to carry an electrostatic charge and formed so that electrodes of a first charge are positioned near electrodes of a second charge. Connectors extend through the base plate to the electrodes to couple the electrodes to a source of electrostatic charge. | 11-19-2015 |
20160064267 | SEALING STRUCTURE FOR WORKPIECE TO SUBSTRATE BONDING IN A PROCESSING CHAMBER - A sealing structure is between a workpiece or substrate and a carrier for plasma processing. In one example, a substrate carrier has a top surface for holding a substrate, the top surface having a perimeter and a resilient sealing ridge on the perimeter of the top surface to contact the substrate when the substrate is being carried on the carrier. | 03-03-2016 |
Patent application number | Description | Published |
20090233438 | SELF-IONIZED AND INDUCTIVELY-COUPLED PLASMA FOR SPUTTERING AND RESPUTTERING - A magnetron sputter reactor for sputtering deposition materials such as tantalum, tantalum nitride and copper, for example, and its method of use, in which self-ionized plasma (SIP) sputtering and inductively coupled plasma (ICP) sputtering are promoted, either together or alternately, in the same or different chambers. Also, bottom coverage may be thinned or eliminated by ICP resputtering in one chamber and SIP in another. SIP is promoted by a small magnetron having poles of unequal magnetic strength and a high power applied to the target during sputtering. ICP is provided by one or more RF coils which inductively couple RF energy into a plasma. The combined SIP-ICP layers can act as a liner or barrier or seed or nucleation layer for hole. In addition, an RF coil may be sputtered to provide protective material during ICP resputtering. In another chamber an array of auxiliary magnets positioned along sidewalls of a magnetron sputter reactor on a side towards the wafer from the target. The magnetron preferably is a small, strong one having a stronger outer pole of a first magnetic polarity surrounding a weaker outer pole of a second magnetic polarity and rotates about the central axis of the chamber. The auxiliary magnets preferably have the first magnetic polarity to draw the unbalanced magnetic field component toward the wafer. The auxiliary magnets may be either permanent magnets or electromagnets. | 09-17-2009 |
20140305802 | SELF-IONIZED AND INDUCTIVELY-COUPLED PLASMA FOR SPUTTERING AND RESPUTTERING - A magnetron sputter reactor for sputtering deposition materials such as tantalum, tantalum nitride and copper, for example, and its method of use, in which self-ionized plasma (SIP) sputtering and inductively coupled plasma (ICP) sputtering are promoted, either together or alternately, in the same or different chambers. Also, bottom coverage may be thinned or eliminated by ICP resputtering in one chamber and SIP in another. SIP is promoted by a small magnetron having poles of unequal magnetic strength and a high power applied to the target during sputtering. ICP is provided by one or more RF coils which inductively couple RF energy into a plasma. The combined SIP-ICP layers can act as a liner or barrier or seed or nucleation layer for hole. In addition, an RF coil may be sputtered to provide protective material during ICP resputtering. In another chamber an array of auxiliary magnets positioned along sidewalls of a magnetron sputter reactor on a side towards the wafer from the target. The magnetron preferably is a small, strong one having a stronger outer pole of a first magnetic polarity surrounding a weaker outer pole of a second magnetic polarity and rotates about the central axis of the chamber. The auxiliary magnets preferably have the first magnetic polarity to draw the unbalanced magnetic field component toward the wafer. The auxiliary magnets may be either permanent magnets or electromagnets. | 10-16-2014 |
Patent application number | Description | Published |
20160133490 | METHODS AND APPARATUS FOR TRANSFERRING A SUBSTRATE - Embodiments method and apparatus for transferring a substrate are provided herein. In some embodiments, a substrate cassette includes a body having an upper portion and a lower portion, the upper portion and the lower portion defining an interior volume when the upper portion is coupled to the lower portion; a locking mechanism moveable between a locked position, in which the upper and lower portions are coupled, and an unlocked position, in which the lower portion can be separated from the upper portion; and a load distribution plate coupled to an upper surface of the upper portion along an edge of the upper portion to distribute a load applied to the load distribution plate. | 05-12-2016 |
20160133491 | MULTI-CASSETTE CARRYING CASE - Embodiments of multi-cassette carrying cases are provided herein. In some embodiments a multi-cassette carrying case includes: a body having an inner volume; a door coupled to the body to selectively seal off the inner volume; and a plurality of cassette holders disposed in the inner volume to hold one or more substrate cassettes. In some embodiments, a method of transferring substrates includes: placing a substrate in a substrate cassette, wherein an inner volume of the substrate cassette is sealed from an environment outside of the substrate cassette; and placing the substrate cassette in a multi-cassette carrying case. | 05-12-2016 |
20160133494 | SUBSTRATE TRANSFER CHAMBER - Embodiments of substrate transfer chambers are provided herein. In some embodiments, a substrate transfer chamber includes a body having an interior volume, wherein a bottom portion of the body includes a first opening; an adapter plate coupled to the bottom portion of the body to couple the substrate transfer chamber to a load lock chamber of a substrate processing system; wherein the adapter plate includes a second opening aligned with the first opening to fluidly couple the interior volume with an inner volume of the load lock chamber; a cassette support disposed in the interior volume to support a substrate cassette; and a lift actuator coupled to the cassette support to lower or raise the substrate cassette into or out of the load lock chamber. | 05-12-2016 |
Patent application number | Description | Published |
20090287823 | METHOD AND SYSTEM FOR SERVER CONSOLIDATION USING A HILL CLIMBING ALGORITHM - A system and method for consolidating a plurality of resources on a plurality of data processing units (DPUs) in a data processing network is provided. The method includes selecting a first DPU having a highest DPU volume among the plurality of DPUs. The method further includes calculating an angle made by a first DPU vector of the first DPU with a horizontal dimension of a multi-dimensional chart using first DPU co-ordinates from the plurality of DPU co-ordinates. Further, the method includes calculating an angle made by a first resource vector of a first resource to be assigned to the first DPU with a horizontal dimension of the multi-dimensional chart. Thereafter, the first resource is assigned to the first DPU, when a deviation of the first resource vector from the first DPU vector is minimum among the plurality of resources. | 11-19-2009 |
20100042723 | METHOD AND SYSTEM FOR MANAGING LOAD IN A NETWORK - A method for managing load in a network comprising a first set of hosts, a second set of hosts and a centralized server is provided. A virtual machine runs on each of the first set of hosts. The centralized server receives resource donation information from each of the second set of hosts that are underutilized. Further, a load surge indicating additional tasks to be performed by the first set of hosts and the second set of hosts is identified. Next, the centralized server negotiates with the second set of hosts for modification of the resource donation information. Thereafter, one or more hosts are determined, based on the resource donation information and the load surge. These hosts create a virtual machine, based on the resource donation information, and become a part of the first set of hosts. The centralized server delegates the additional tasks among the first set of hosts. | 02-18-2010 |
20150134637 | System and Method for Sharding a Graph Database - The present invention provides a method and system for sharding a graph database. The graph computing includes one or more processors, and a memory module. The memory module contains instructions that, when executed by the one or more processors, causes the one or more processors to perform a set of steps including identifying a first set of nodes from a plurality of nodes and a second set of nodes from a plurality of nodes, generating one or more sub graph shards from the graph database, and storing the one or more sub graph shards on one or more data stores. Each sub graph shard of the one or more sub graph shards includes at least one node from the first set of nodes and a replica of the second set of nodes. | 05-14-2015 |