Patent application number | Description | Published |
20100017010 | MONITORING A PROCESS SECTOR IN A PRODUCTION FACILITY - Monitoring a process sector in a production facility includes establishing a tool defect index associated with a process sector in the production facility. The tool defect index includes a signal representing a defect factor associated with a tool in the process sector. Monitoring the process also requires determining whether the defect factor is a known defect factor or an unknown defect factor, and analyzing a unit from the tool if the defect factor is an unknown defect factor. Monitoring the process further requires identifying at least one defect on the unit from the tool, establishing that the at least one defect is a significant defect, determining cause of the significant defect, and creating an alert indicating that the tool associated with the process sector is producing units having significant defects. | 01-21-2010 |
20100032829 | STRUCTURES AND METHODS FOR IMPROVING SOLDER BUMP CONNECTIONS IN SEMICONDUCTOR DEVICES - Structures with improved solder bump connections and methods of fabricating such structures are provided herein. The structure includes a trench formed in a dielectric layer which has at least a portion thereof devoid of a fluorine boundary layer. The structure further includes a copper wire in the trench having at least a bottom portion thereof in contact with the non-fluoride boundary layer of the trench. A lead free solder bump is in electrical contact with the copper wire. | 02-11-2010 |
20120129336 | STRUCTURES AND METHODS FOR IMPROVING SOLDER BUMP CONNECTIONS IN SEMICONDUCTOR DEVICES - Structures with improved solder bump connections and methods of fabricating such structures are provided herein. The structure includes a trench formed in a dielectric layer which has at least a portion thereof devoid of a fluorine boundary layer. The structure further includes a copper wire in the trench having at least a bottom portion thereof in contact with the non-fluoride boundary layer of the trench. A lead free solder bump is in electrical contact with the copper wire. | 05-24-2012 |
20140148003 | REPLACEMENT METAL GATE TRANSISTORS USING BI-LAYER HARDMASK - Methods of fabricating replacement metal gate transistors using bi-layer a hardmask are disclosed. By utilizing a bi-layer hardmask comprised of a first layer of nitride, followed by a second layer of oxide, the topography issues caused by transition regions of gates are mitigated, which simplifies downstream processing steps and improves yield. | 05-29-2014 |
20140151772 | UNIFORM FINFET GATE HEIGHT - A method including providing fins etched from a semiconductor substrate and covered by an oxide layer and a nitride layer, the oxide layer being located between the fins and the nitride layer, removing a portion of the fins to form an opening, forming a dielectric spacer on a sidewall of the opening, and filling the opening with a fill material, wherein a top surface of the fill material is substantially flush with a top surface of the nitride layer. The method may further include forming a deep trench capacitor in-line with one of the fins, removing the nitride layer to form a gap between the fins and the fill material, wherein the fill material has re-entrant geometry extending over the gap, and removing the re-entrant geometry and causing the gap between the fins and the fill material to widen. | 06-05-2014 |
Patent application number | Description | Published |
20090075472 | METHODS TO MITIGATE PLASMA DAMAGE IN ORGANOSILICATE DIELECTRICS - Methods of minimizing or eliminating plasma damage to low k and ultra low k organosilicate intermetal dielectric layers are provided. The reduction of the plasma damage is effected by interrupting the etch and strip process flow at a suitable point to add an inventive treatment which protects the intermetal dielectric layer from plasma damage during the plasma strip process. Reduction or elimination of a plasma damaged region in this manner also enables reduction of the line bias between a line pattern in a photoresist and a metal line formed therefrom, and changes in the line width of the line trench due to a wet clean after the reactive ion etch employed for formation of the line trench and a via cavity. The reduced line bias has a beneficial effect on electrical yields of a metal interconnect structure. | 03-19-2009 |
20090146211 | GROUNDING FRONT-END-OF-LINE STRUCTURES ON A SOI SUBSTRATE - Structures and a method are disclosed for grounding gate-stack and/or silicon active region front-end-of-line structures on a silicon-on-insulator (SOI) substrate, which may be used as test structures for VC inspection. In one embodiment, a structure includes a grounded bulk silicon substrate having the SOI substrate thereover, the SOI substrate including a silicon-on-insulator (SOI) layer and a buried oxide (BOX) layer; the silicon active region having at least one finger element within the SOI layer, the at least one finger element isolated by a shallow trench isolation (STI) layer; and a polysilicon ground intersecting the at least one finger element and extending through the STI layer and the BOX layer to the grounded bulk silicon substrate, the polysilicon ground contacting the silicon active region and the grounded bulk silicon substrate. | 06-11-2009 |
20120329269 | METHODS TO MITIGATE PLASMA DAMAGE IN ORGANOSILICATE DIELECTRICS - Methods of minimizing or eliminating plasma damage to low k and ultra low k organosilicate intermetal dielectric layers are provided. The reduction of the plasma damage is effected by interrupting the etch and strip process flow at a suitable point to add an inventive treatment which protects the intermetal dielectric layer from plasma damage during the plasma strip process. Reduction or elimination of a plasma damaged region in this manner also enables reduction of the line bias between a line pattern in a photoresist and a metal line formed therefrom, and changes in the line width of the line trench due to a wet clean after the reactive ion etch employed for formation of the line trench and a via cavity. The reduced line bias has a beneficial effect on electrical yields of a metal interconnect structure. | 12-27-2012 |
Patent application number | Description | Published |
20110037493 | PROBE-ABLE VOLTAGE CONTRAST TEST STRUCTURES - Test structures and method for detecting defects using the same. A probe-able voltage contrast (VC) comb test structure that includes first, second and third probe pads, a comb-like structure including grounded tines, floating tines between the grounded tines, switching devices coupled with an end portion of each floating tine, and connecting the floating tines to the second probe pad, and the third probe pad being a control pad which controls the switching devices. A probe-able VC serpentine test structure that includes first, second, third and fourth probe pads, a comb-like structure including grounded tines, floating tines between the grounded tines and each floating tine connected together between the second and third probe pads, switching devices connected to an end portion of each floating tine and connecting the floating tines to the second and third probe pads, and the fourth probe pad being a control pad which controls the switching devices. | 02-17-2011 |
20120319714 | PROBE-ABLE VOLTAGE CONTRAST TEST STRUCTURES - Test structures and method for detecting defects using the same. A probe-able voltage contrast (VC) comb test structure that includes first, second and third probe pads, a comb-like structure including grounded tines, floating tines between the grounded tines, switching devices coupled with an end portion of each floating tine, and connecting the floating tines to the second probe pad, and the third probe pad being a control pad which controls the switching devices. A probe-able VC serpentine test structure that includes first, second, third and fourth probe pads, a comb-like structure including grounded tines, floating tines between the grounded tines and each floating tine connected together between the second and third probe pads, switching devices connected to an end portion of each floating tine and connecting the floating tines to the second and third probe pads, and the fourth probe pad being a control pad which controls the switching devices. | 12-20-2012 |
20120319715 | PROBE-ABLE VOLTAGE CONTRAST TEST STRUCTURES - Test structures and method for detecting defects using the same. A probe-able voltage contrast (VC) comb test structure that includes first, second and third probe pads, a comb-like structure including grounded tines, floating tines between the grounded tines, switching devices coupled with an end portion of each floating tine, and connecting the floating tines to the second probe pad, and the third probe pad being a control pad which controls the switching devices. A probe-able VC serpentine test structure that includes first, second, third and fourth probe pads, a comb-like structure including grounded tines, floating tines between the grounded tines and each floating tine connected together between the second and third probe pads, switching devices connected to an end portion of each floating tine and connecting the floating tines to the second and third probe pads, and the fourth probe pad being a control pad which controls the switching devices. | 12-20-2012 |
20120319716 | PROBE-ABLE VOLTAGE CONTRAST TEST STRUCTURES - Test structures and method for detecting defects using the same. A probe-able voltage contrast (VC) comb test structure that includes first, second and third probe pads, a comb-like structure including grounded tines, floating tines between the grounded tines, switching devices coupled with an end portion of each floating tine, and connecting the floating tines to the second probe pad, and the third probe pad being a control pad which controls the switching devices. A probe-able VC serpentine test structure that includes first, second, third and fourth probe pads, a comb-like structure including grounded tines, floating tines between the grounded tines and each floating tine connected together between the second and third probe pads, switching devices connected to an end portion of each floating tine and connecting the floating tines to the second and third probe pads, and the fourth probe pad being a control pad which controls the switching devices. | 12-20-2012 |