Patent application number | Description | Published |
20110100420 | PHOTOVOLTAIC MODULE WITH A CONTROLLABLE INFRARED PROTECTION LAYER - An apparatus, system, and method are disclosed for a photovoltaic module, the photovoltaic module comprising a plurality of photovoltaic cells, a controllable infrared protection layer, and a protection switching means. The controllable infrared protection layer is for reducing the infrared radiation absorbed by the photovoltaic module, where the controllable infrared protection layer has a first state and a second state. When the infrared protection layer is in the first state the transmission of infrared radiation to the photovoltaic cells is higher than when the infrared protection layer is in the second state. The protection switching means is for switching the controllable infrared protection layer between the first state and the second state. | 05-05-2011 |
20110260326 | STRUCTURES AND METHODS FOR AIR GAP INTEGRATION - Methods for producing air gap-containing metal-insulator interconnect structures for VLSI and ULSI devices using a photo-patternable low k material as well as the air gap-containing interconnect structure that is formed are disclosed. More particularly, the methods described herein provide interconnect structures built in a photo-patternable low k material in which air gaps of different depths are defined by photolithography in the photo-patternable low k material. In the methods of the present invention, no etch step is required to form the air gaps. Since no etch step is required in forming the air gaps within the photo-patternable low k material, the methods disclosed in this invention provide highly reliable interconnect structures. | 10-27-2011 |
20110272810 | STRUCTURE AND METHOD FOR AIR GAP INTERCONNECT INTEGRATION - Methods for producing air gap-containing metal-insulator interconnect structures for VLSI and ULSI devices using a photo-patternable low k material as well as the air gap-containing interconnect structure that is formed are disclosed. More particularly, the methods described herein provide interconnect structures built in a photo-patternable low k material in which air gaps are defined by photolithography in the photo-patternable low k material. In the methods of the present invention, no etch step is required to form the air gaps. Since no etch step is required in forming the air gaps within the photo-patternable low k material, the methods disclosed in this invention provide highly reliable interconnect structures. | 11-10-2011 |
20120280398 | METHOD FOR AIR GAP INTERCONNECT INTEGRATION USING PHOTO-PATTERNABLE LOW K MATERIAL - Methods for producing air gap-containing metal-insulator interconnect structures for VLSI and ULSI devices using a photo-patternable low k material as well as the air gap-containing interconnect structure that is formed are disclosed. More particularly, the methods described herein provide interconnect structures built in a photo-patternable low k material in which air gaps are defined by photolithography in the photo-patternable low k material. In the methods of the present invention, no etch step is required to form the air gaps. Since no etch step is required in forming the air gaps within the photo-patternable low k material, the methods disclosed in this invention provide highly reliable interconnect structures. | 11-08-2012 |
20140131880 | METHODS FOR FABRICATION OF AN AIR GAP-CONTAINING INTERCONNECT STRUCTURE - Methods for producing air gap-containing metal-insulator interconnect structures for VLSI and ULSI devices using a photo-patternable low k material as well as the air gap-containing interconnect structure that is formed are disclosed. More particularly, the methods described herein provide interconnect structures built in a photo-patternable low k material in which air gaps are defined by photolithography in the photo-patternable low k material. In the methods of the present invention, no etch step is required to form the air gaps. Since no etch step is required in forming the air gaps within the photo-patternable low k material, the methods disclosed in this invention provide highly reliable interconnect structures. | 05-15-2014 |
Patent application number | Description | Published |
20100314768 | INTERCONNECT STRUCTURE FABRICATED WITHOUT DRY PLASMA ETCH PROCESSING - An interconnect structure within a microelectronic structure and a method for fabricating the interconnect structure within the microelectronic structure use a developable bottom anti-reflective coating layer and at least one imageable inter-level dielectric layer located thereupon over a substrate that includes a base dielectric layer and a first conductor layer located and formed embedded within the base dielectric layer. Incident to use of the developable bottom anti-reflective coating layer and the at least one imageable inter-level dielectric layer, an aperture, such as but not limited to a dual damascene aperture, may be formed through the at least one imageable inter-level dielectric layer and the developable anti-reflective coating layer to expose a capping layer located and formed upon the first conductor layer, absent use of a dry plasma etch method when forming the interconnect structure within the microelectronic structure. | 12-16-2010 |
20110311825 | SELECTIVE ETCH BACK PROCESS FOR CARBON NANOTUBES INTERGRATION - The present disclosure relates to a method for selectively etching-back a polymer matrix to expose tips of carbon nanotubes comprising:
| 12-22-2011 |
20130009312 | INTERCONNECT STRUCTURE FABRICATED WITHOUT DRY PLASMA ETCH PROCESSING - An interconnect structure within a microelectronic structure and a method for fabricating the interconnect structure within the microelectronic structure use a developable bottom anti-reflective coating layer and at least one imageable inter-level dielectric layer located thereupon over a substrate that includes a base dielectric layer and a first conductor layer located and formed embedded within the base dielectric layer. Incident to use of the developable bottom anti-reflective coating layer and the at least one imageable inter-level dielectric layer, an aperture, such as but not limited to a dual damascene aperture, may be formed through the at least one imageable inter-level dielectric layer and the developable anti-reflective coating layer to expose a capping layer located and formed upon the first conductor layer, absent use of a dry plasma etch method when forming the interconnect structure within the microelectronic structure. | 01-10-2013 |
Patent application number | Description | Published |
20110108989 | PROCESS FOR REVERSING TONE OF PATTERNS ON INTEGERATED CIRCUIT AND STRUCTURAL PROCESS FOR NANOSCALE FABRICATION - A process to produce an airgap on a substrate having a dielectric layer comprises defining lines by lithography where airgaps are required. The lines' dimensions are shrunk by a trimming process (isotropic etching). The tone of the patterns is reversed by applying a planarizing layer which is etched down to the top of the patterns. The photoresist is removed, leading to sub-lithographic trenches which are transferred into a cap layer and eventually into the dielectric between two metal lines. The exposed dielectric is eventually damaged, and is etched out, leading to airgaps between metal lines. The gap is sealed by the pinch-off occurring during the deposition of the subsequent dielectric. | 05-12-2011 |
20110115094 | STRUCTURES AND METHODS FOR PHOTO-PATTERNABLE LOW-k (PPLK) INTEGRATION - A single damascene or dual damascene interconnect structure fabricated with a photo-patternable low-k dielectric (PPLK) which is cured after etching. This interconnect method prevents the PPLK damage and the tapering of the edges of the interconnect structure. In one embodiment, the method of the present invention includes depositing a photo-patternable low-k (PPLK) material atop an initial structure. The initial structure can include a dielectric cap, an antireflective coating (ARC), or a material stack including the same. The at least one PPLK material is patterned, creating a single damascene structure. For dual damascene structures, a second PPLK layer is coated and patterned. An etch process is performed to transfer the pattern for the PPLK material into at least a portion of the substrate, typically into the dielectric cap and/or ARC using processes known by those skilled in the art (typically fluorocarbon-based plasmas). A diffusion liner deposition can follow the etch process. An electrically conductive material can also be deposited. The diffusion liner and the electrically conductive material can be polished using chemical mechanical polishing. The resulting structure is cured anytime after etching order to transform the resist like PPLK into a permanent low-k material that remains within the structure. | 05-19-2011 |
20110121457 | Process for Reversing Tone of Patterns on Integrated Circuit and Structural Process for Nanoscale Production - A process to produce an airgap on a substrate having a dielectric layer comprises defining lines by lithography where airgaps are required. The lines' dimensions are shrunk by a trimming process (isotropic etching). The tone of the patterns is reversed by applying a planarizing layer which is etched down to the top of the patterns. The photoresist is removed, leading to sub-lithographic trenches which are transferred into a cap layer and eventually into the dielectric between two metal lines. The exposed dielectric is eventually damaged, and is etched out, leading to airgaps between metal lines. The gap is sealed by the pinch-off occurring during the deposition of the subsequent dielectric. | 05-26-2011 |
20110221062 | METHODS FOR FABRICATION OF AN AIR GAP-CONTAINING INTERCONNECT STRUCTURE - Methods for producing air gap-containing metal-insulator interconnect structures for VLSI and ULSI devices using a photo-patternable low k material as well as the air gap-containing interconnect structure that is formed are disclosed. More particularly, the methods described herein provide interconnect structures built in a photo-patternable low k material in which air gaps are defined by photolithography in the photo-patternable low k material. In the methods of the present invention, no etch step is required to form the air gaps. Since no etch step is required in forming the air gaps within the photo-patternable low k material, the methods disclosed in this invention provide highly reliable interconnect structures. | 09-15-2011 |
20110311781 | METHOD OF PATTERNING PHOTOSENSITIVE MATERIAL ON A SUBSTRATE CONTAINING A LATENT ACID GENERATOR - The present disclosure relates to a method of patterning a photosensitive material on a polymeric fill matrix comprising at least one latent photoacid generator; and a structure prepared according to said method. The method comprises:
| 12-22-2011 |
20120276657 | METHOD OF PATTERNING OF MAGNETIC TUNNEL JUNCTIONS - Embodiments of the invention generally relate to methods for fabricating devices on semiconductor substrates. More specifically, embodiments of the invention relate to methods of patterning magnetic materials. Certain embodiments described herein use a reducing chemistry containing a hydrogen gas or hydrogen containing gas with an optional dilution gas at temperatures ranging from 20 to 300 degrees Celsius at a substrate bias less than 1,000 DC voltage to reduce the amount of sputtering and redeposition. Exemplary hydrogen containing gases which may be used with the embodiments described herein include NH | 11-01-2012 |
20120301980 | METHODOLOGY FOR EVALUATION OF ELECTRICAL CHARACTERISTICS OF CARBON NANOTUBES - The present disclosure relates to a structure comprising
| 11-29-2012 |
20130001781 | STRUCTURES AND METHODS FOR PHOTO-PATTERNABLE LOW-k (PPLK) INTEGRATION - An interconnect structure is provided which includes at least one patterned and cured low-k material located directly on a surface of a substrate; and at least one least one conductively filled region embedded within an interconnect pattern located within the at least one patterned and cured low-k material, wherein the at least one conductively filled region has an inflection point at a lower region of the interconnect pattern that is in proximity to an upper surface of the substrate and the interconnect region having an upper region that has substantially straight sidewalls. | 01-03-2013 |
20130056874 | Protection of intermetal dielectric layers in multilevel wiring structures - A semiconductor device is accepted at a stage of its fabrication, at which stage the device includes a diffusion-barrier cap-material (DBCM) layer and an intermetal dielectric layer covering the DBCM layer. The DBCM layer is exposed and it is suitable for removal by an etching procedure in a portion of a pattern contained in the intermetal dielectric layer. A silylation treatment is performed on the semiconductor device prior to the etching procedure for removing the DBCM layer. The intermetal dielectric layer of the completed device has surfaces in contact with metal interconnects and metal vias, and it may have an excess of carbon content near at least a portion of the these surfaces. | 03-07-2013 |