Patent application number | Description | Published |
20080254630 | DEVICE AND METHODOLOGY FOR REDUCING EFFECTIVE DIELECTRIC CONSTANT IN SEMICONDUCTOR DEVICES - Method of manufacturing a semiconductor device structure, including the steps of providing a structure having an insulator layer with at least one interconnect, forming a sub lithographic template mask over the insulator layer, and selectively etching the insulator layer through the sub lithographic template mask to form sub lithographic features spanning to a sidewall of the at least one interconnect. | 10-16-2008 |
20080265382 | Nonlithographic Method to Produce Self-Aligned Mask, Articles Produced by Same and Compositions for Same - A method for forming a self aligned pattern on an existing pattern on a substrate comprising applying a coating of a solution containing a masking material in a carrier, the masking material having an affinity for portions of the existing pattern; and allowing at least a portion of the masking material to preferentially assemble to the portions of the existing pattern. The pattern may be comprised of a first set of regions of the substrate having a first atomic composition and a second set of regions of the substrate having a second atomic composition different from the first composition. The first set of regions may include one or more metal elements and the second set of regions may include a dielectric. The first and second regions may be treated to have different surface properties. Structures made in accordance with the method. Compositions useful for practicing the method. | 10-30-2008 |
20080265415 | Nonlithographic Method to Produce Self-Aligned Mask, Articles Produced by Same and Compositions for Same - A method for forming a self aligned pattern on an existing pattern on a substrate comprising applying a coating of a solution containing a masking material in a carrier, the masking material having an affinity for portions of the existing pattern; and allowing at least a portion of the masking material to preferentially assemble to the portions of the existing pattern. The pattern may be comprised of a first set of regions of the substrate having a first atomic composition and a second set of regions of the substrate having a second atomic composition different from the first composition. The first set of regions may include one or more metal elements and the second set of regions may include a dielectric. The first and second regions may be treated to have different surface properties. Structures made in accordance with the method. Compositions useful for practicing the method. | 10-30-2008 |
20080284039 | INTERCONNECT STRUCTURES WITH TERNARY PATTERNED FEATURES GENERATED FROM TWO LITHOGRAPHIC PROCESSES - A method for fabricating an interconnect structure for interconnecting a semiconductor substrate to have three distinct patterned structures such that the interconnect structure provides both a low k and high structural integrity. The method includes depositing an interlayer dielectric onto the semiconductor substrate, forming a first pattern within the interlayer dielectric material by a first lithographic process that results in both via features and ternary features being formed in the interconnect structure. The method further includes forming a second pattern within the interlayer dielectric material by a second lithographic process to form line features within the interconnect structure. Hence the method forms the three separate distinct patterned structures using only two lithographic processes for each interconnect level. | 11-20-2008 |
20090014880 | DUAL DAMASCENE PROCESS FLOW ENABLING MINIMAL ULK FILM MODIFICATION AND ENHANCED STACK INTEGRITY - Interconnect structures possessing an organosilicate glass interlayer dielectric material with minimal stoichiometeric modification and optionally an intact organic adhesion promoter for use in semiconductor devices are provided herein. The interconnect structure is capable of delivering improved device performance, functionality and reliability owing to the reduced effective dielectric constant of the stack compared with that of those conventionally employed because of the use of a sacrificial polymeric material deposited onto the dielectric and optional organic adhesion promoter during the barrier open step done prior to ashing the patterning material. This sacrificial film protects the dielectric and optional organic adhesion promoter from modification/consumption during the subsequent ashing step during which the polymeric film is removed. | 01-15-2009 |
20090061237 | LOW k POROUS SiCOH DIELECTRIC AND INTEGRATION WITH POST FILM FORMATION TREATMENT - A porous SiCOH (e.g., p-SiCOH) dielectric film in which the stress change caused by increased tetrahedral strain is minimized by post treatment in unsaturated Hydrocarbon ambient. The inventive p-SiCOH dielectric film has more —(CHx) and less Si—O—H and Si—H bondings as compared to prior art p-SiCOH dielectric films. Moreover, a stable pSiOCH dielectric film is provided in which the amount of Si—OH (silanol) and Si—H groups at least within the pores has been reduced by about 90% or less by the post treatment. Hence, the inventive p-SiCOH dielectric film has hydrophobicity improvement as compared with prior art p-SiCOH dielectric films. In the present invention, a p-SiCOH dielectric film is produced that is flexible since the pores of the inventive film include stabilized crosslinking —(CH | 03-05-2009 |
20090061649 | LOW k POROUS SiCOH DIELECTRIC AND INTEGRATION WITH POST FILM FORMATION TREATMENT - A porous SiCOH (e.g., p-SiCOH) dielectric film in which the stress change caused by increased tetrahedral strain is minimized by post treatment in unsaturated Hydrocarbon ambient. The inventive p-SiCOH dielectric film has more —(CHx) and less Si—O—H and Si—H bondings as compared to prior art p-SiCOH dielectric films. Moreover, a stable pSiOCH dielectric film is provided in which the amount of Si—OH (silanol) and Si—H groups at least within the pores has been reduced by about 90% or less by the post treatment. Hence, the inventive p-SiCOH dielectric film has hydrophobicity improvement as compared with prior art p-SiCOH dielectric films. In the present invention, a p-SiCOH dielectric film is produced that is flexible since the pores of the inventive film include stabilized crosslinking —(CH | 03-05-2009 |
20090140428 | AIR GAP STRUCTURE HAVING PROTECTIVE METAL SILICIDE PADS ON A METAL FEATURE - A hard mask is formed on an interconnect structure comprising a low-k material layer and a metal feature embedded therein. A block polymer is applied to the hard mask layer, self-assembled, and patterned to form a polymeric matrix of a polymeric block component and containing cylindrical holes. The hard mask and the low-k material layer therebelow are etched to form cavities. A conductive material is plated on exposed metallic surfaces including portions of top surfaces of the metal feature to form metal pads. Metal silicide pads are formed by exposure of the metal pads to a silicon containing gas. An etch is performed to enlarge and merge the cavities in the low-k material layer. The metal feature is protected from the etch by the metal silicide pads. An interconnect structure having an air gap and free of defects to surfaces of the metal feature is formed. | 06-04-2009 |
20090200636 | SUB-LITHOGRAPHIC DIMENSIONED AIR GAP FORMATION AND RELATED STRUCTURE - Sub-lithographic dimensioned air gap formation and related structure are disclosed. In one embodiment, a method includes forming a dielectric layer including interconnects on a substrate; depositing a cap layer on the dielectric layer; depositing a photoresist over the cap layer; patterning the photoresist to include a first trench pattern at most partially overlying the interconnects; forming a spacer within the first trench pattern to form a second trench pattern having a sub-lithographic dimension; transferring the second trench pattern into the cap layer and into the dielectric layer between the interconnects; and depositing another dielectric layer to form an air gap by pinching off the trench in the dielectric layer. | 08-13-2009 |
20090200683 | INTERCONNECT STRUCTURES WITH PARTIALLY SELF ALIGNED VIAS AND METHODS TO PRODUCE SAME - An interconnect structure having partially self aligned vias with an interlayer dielectric layer on a substrate, containing at least two conducting metal lines that traverse parallel to the substrate and at least two conducting metal vias that are orthogonal to the substrate. A method of producing the self aligned vias by depositing an interlayer dielectric layer onto a substrate, depositing at least one hardmask onto the interlayer dielectric layer, lithographically forming a via pattern with elongated via features and lithographically forming a line pattern in either order, then either transferring the line patterns first into the interlayer dielectric layer forming line features or transferring the via pattern first into the interlayer dielectric layer as long as the patterns overlap to forming self aligned via features, depositing conducting metals and filling regions corresponding to the line and via features, and planarizing and removing excess metal from the line and via features. | 08-13-2009 |
20090294982 | INTERCONNECT STRUCTURES WITH TERNARY PATTERNED FEATURES GENERATED FROM TWO LITHOGRAPHIC PROCESSES - A method for fabricating an interconnect structure for interconnecting a semiconductor substrate to have three distinct patterned structures such that the interconnect structure provides both a low k and high structural integrity. The method includes depositing an interlayer dielectric onto the semiconductor substrate, forming a first pattern within the interlayer dielectric material by a first lithographic process that results in both via features and ternary features being formed in the interconnect structure. The method further includes forming a second pattern within the interlayer dielectric material by a second lithographic process to form line features within the interconnect structure. Hence the method forms the three separate distinct patterned structures using only two lithographic processes for each interconnect level. | 12-03-2009 |
20090311859 | METHOD FOR ENABLING HARD MASK FREE INTEGRATION OF ULTRA LOW-K MATERIALS AND STRUCTURES PRODUCED THEREBY - A method of fabricating an interconnect structure on a substrate includes steps of: providing a dielectric with at least one etched opening; filling the at least one etched opening with at least one conductive material; planarizing the conductive material to provide a planarized structure; subjecting the planarized structure to a plasma preclean process; and exposing the planarized structure to a silylating repair agent which is a silane derivative; and forming a dielectric cap layer on the planarized structure. | 12-17-2009 |
20100041227 | METHODS FOR INCORPORATING HIGH DIELECTRIC MATERIALS FOR ENHANCED SRAM OPERATION AND STRUCTURES PRODUCED THEREBY - Methods for fabricating a hybrid interconnect structure that possesses a higher interconnect capacitance in one set of regions than in other regions on the same microelectronic chip. Several methods to fabricate such a structure are provided. Circuit implementations of such hybrid interconnect structures are described that enable increased static noise margin and reduce the leakage in SRAM cells and common power supply voltages for SRAM and logic in such a chip. Methods that enable combining these circuit benefits with higher interconnect performance speed and superior mechanical robustness in such chips are also taught. | 02-18-2010 |
20100055442 | METHOD OF PE-ALD OF SiNxCy AND INTEGRATION OF LINER MATERIALS ON POROUS LOW K SUBSTRATES - A method of depositing a SiN | 03-04-2010 |
20100187689 | SEMICONDUCTOR CHIPS INCLUDING PASSIVATION LAYER TRENCH STRUCTURE - An integrated circuit including an active region a passive region and a cut line in the passive region includes a passivation layer that includes an outer nitride layer over an oxide layer. The integrated circuit also includes a crack stop below the passivation layer and in the passive region, and a solder ball in the active region. The passivation layer has a trench formed therein in a location that is further from the active region than the crack stop and closer to the active region than the cut line, the trench passing completely through the outer nitride layer and a least a portion of the way through the oxide layer. | 07-29-2010 |
20100285667 | METHOD TO PRESERVE THE CRITICAL DIMENSION (CD) OF AN INTERCONNECT STRUCTURE - A method of restoring the dielectric constant, loss and leakage of an exposed surface of a low k dielectric material caused during dry etching of the low k dielectric material prior to the removal of the damaged layer by wet etch chemistries is provided. Once restored, the surface of the dielectric material will no longer be susceptible to removal by the highly anisotropic wet etching process. However, the wet etch will still pose an advantage as it can remove any etch/ash residues at the bottom of a feature formed into the low k dielectric material. | 11-11-2010 |
20110003402 | RECOVERY OF HYDROPHOBICITY OF LOW-K AND ULTRA LOW-K ORGANOSILICATE FILMS USED AS INTER METAL DIELECTRICS - Often used to reduce the RC delay in integrated circuits are dielectric films of porous organosilicates which have a silica like backbone with alkyl or aryl groups (to add hydrophobicity to the materials and create free volume) attached directly to the Si atoms in the network. Si—R bonds rarely survive an exposure to plasmas or chemical treatments commonly used in processing; this is especially the case in materials with an open cell pore structure. When Si—R bonds are broken, the materials lose hydrophobicity, due to formation of hydrophilic silanols and low dielectric constant is compromised. A method by which the hydrophobicity of the materials is recovered using a novel class of silylation agents which may have the general formula (R | 01-06-2011 |
20110092067 | AIR GAP STRUCTURE HAVING PROTECTIVE METAL SILICIDE PADS ON A METAL FEATURE - A hard mask is formed on an interconnect structure comprising a low-k material layer and a metal feature embedded therein. A block polymer is applied to the hard mask layer, self-assembled, and patterned to form a polymeric matrix of a polymeric block component and containing cylindrical holes. The hard mask and the low-k material layer therebelow are etched to form cavities. A conductive material is plated on exposed metallic surfaces including portions of top surfaces of the metal feature to form metal pads. Metal silicide pads are formed by exposure of the metal pads to a silicon containing gas. An etch is performed to enlarge and merge the cavities in the low-k material layer. The metal feature is protected from the etch by the metal silicide pads. An interconnect structure having an air gap and free of defects to surfaces of the metal feature is formed. | 04-21-2011 |
20110111590 | DEVICE AND METHODOLOGY FOR REDUCING EFFECTIVE DIELECTRIC CONSTANT IN SEMICONDUCTOR DEVICES - Method of manufacturing a structure which includes the steps of providing a structure having an insulator layer with at least one interconnect, forming a sub lithographic template mask over the insulator layer, and selectively etching the insulator layer through the sub lithographic template mask to form sub lithographic features spanning to a sidewall of the plurality of interconnects. | 05-12-2011 |
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 |
20110227232 | CRENULATED WIRING STRUCTURE AND METHOD FOR INTEGRATED CIRCUIT INTERCONNECTS - A method for forming crenulated conductors and a device having crenulated conductors includes forming a hardmask layer on a dielectric layer, and patterning the hardmask layer. Trenches are etched in the dielectric layer using the hardmask layer such that the trenches have shallower portions and deeper portions alternating along a length of the trench. A conductor is deposited in the trenches such that crenulated conductive lines are formed having different depths periodically disposed along the length of the conductive line. | 09-22-2011 |
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 |
20110266682 | MICROELECTRONIC STRUCTURE INCLUDING AIR GAP - A microelectronic structure and a method for fabricating the microelectronic structure provide a plurality of voids interposed between a plurality of conductor layers. The plurality of voids is also located between a liner layer and an inter-level dielectric layer. The voids provide for enhanced electrical performance of the microelectronic structure. | 11-03-2011 |
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 |
20120032311 | MULTI COMPONENT DIELECTRIC LAYER - An in-situ process is described incorporating plasma enhanced chemical vapor deposition comprising flowing at least one of a Si, Si+C, B, Si+B, Si+B+C, and B+C containing precursor, and a N containing precursors at first times and removing the N precursor at second times and starting the flow of an oxidant gas and a porogen gas into the chamber. A dielectric layer is described comprising a network having inorganic random three dimensional covalent bonding throughout the network which contains at least one SiCN, SiCNH, SiN, SiNH, BN, BNH, CBN, CBNH, BSiN, BSiNH, SiCBN and SiCBNH as a first component and a low k dielectric as a second component adjacent thereto. | 02-09-2012 |
20120038056 | INTERCONNECT STRUCTURE FOR IMPROVED TIME DEPENDENT DIELECTRIC BREAKDOWN - The present disclosure provides a method of forming an interconnect to an electrical device. In one embodiment, the method of forming an interconnect includes providing a device layer on a substrate, wherein the device layer comprises at least one electrical device, an intralevel dielectric over the at least one electrical device, and a contact that is in electrical communication with the at least one electrical device. An interconnect metal layer is formed on the device layer, and a tantalum-containing etch mask is formed on a portion of the interconnect metal layer. The interconnect metal layer is etched to provide a trapezoid shaped interconnect in communication with the at least one electrical device. The trapezoid shaped interconnect has a first surface that is in contact with the device layer with a greater width than a second surface of the trapezoid shaped interconnect that is in contact with the tantalum-containing etch mask. | 02-16-2012 |
20120068344 | INTERCONNECT STRUCTURE WITH A PLANAR INTERFACE BETWEEN A SELECTIVE CONDUCTIVE CAP AND A DIELECTRIC CAP LAYER - A selective conductive cap is deposited on exposed metal surfaces of a metal line by electroless plating selective to exposed underlying dielectric surfaces of a metal interconnect structure. A dielectric material layer is deposited on the selective conductive cap and the exposed underlying dielectric layer without a preclean. The dielectric material layer is planarized to form a horizontal planar surface that is coplanar with a topmost surface of the selective conductive cap. A preclean is performed and a dielectric cap layer is deposited on the selective conductive cap and the planarized surface of the dielectric material layer. Because the interface including a surface damaged by the preclean is vertically offset from the topmost surface of the metal line, electromigration of the metal in the metal line along the interface is reduced or eliminated. | 03-22-2012 |
20120111825 | AIR GAP INTERCONNECT STRUCTURES AND METHODS FOR FORMING THE SAME - A metal interconnect structure includes at least a pair of metal lines, a cavity therebetween, and a dielectric metal-diffusion barrier layer located on at least one portion of walls of the cavity. After formation of a cavity between the pair of metal lines, the dielectric metal-diffusion barrier layer is formed on the exposed surfaces of the cavity. A dielectric material layer is formed above the pair of metal lines to encapsulate the cavity. The dielectric metal-diffusion barrier layer prevents diffusion of metal and impurities from one metal line to another metal line and vice versa, thereby preventing electrical shorts between the pair of metal lines. | 05-10-2012 |
20120261828 | INTERCONNECT STRUCTURE AND METHOD FOR FABRICATING ON-CHIP INTERCONNECT STRUCTURES BY IMAGE REVERSAL - An interconnect structure includes a patterned and cured dielectric layer located directly on a surface of a patterned permanent antireflective coating. The patterned and cured dielectric layer and the permanent antireflective coating form shaped openings. The shaped openings include an inverse profile which narrows towards a top of the shaped openings. A conductive structure fills the shaped openings wherein the patterned and cured dielectric layer and the permanent antireflective coating each have a conductively filled region. | 10-18-2012 |
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 |
20120301706 | METHOD OF PE-ALD OF SiNxCy AND INTEGRATION OF LINER MATERIALS ON POROUS LOW K SUBSTRATES - A method of depositing a SiN | 11-29-2012 |
20120306018 | BEOL STRUCTURES INCORPORATING ACTIVE DEVICES AND MECHANICAL STRENGTH - A monolithic integrated circuit and method includes a substrate, a plurality of semiconductor device layers monolithically integrated on the substrate, and a metal wiring layer with vias interconnecting the plurality of semiconductor device layers. The semiconductor device layers are devoid of bonding or joining interface with the substrate. A method of fabricating a monolithic integrated circuit using a single substrate, includes fabricating semiconductor devices on a substrate, fabricating at least one metal wiring layer on the semiconductor devices, forming at least one dielectric layer in integral contact with the at least one metal wiring layer, forming contact openings through the at least one dielectric layer to expose regions of the at least one metal wiring layer, integrally forming, from the substrate, a second semiconductor layer on the dielectric layer, and in contact with the at least one metal wiring layer through the contact openings, and forming a plurality of non-linear semiconductor devices in said second semiconductor layer. | 12-06-2012 |
20120329287 | LOW k POROUS SiCOH DIELECTRIC AND INTEGRATION WITH POST FILM FORMATION TREATMENT - A porous SiCOH dielectric film in which the stress change caused by increased tetrahedral strain is minimized by post treatment in unsaturated Hydrocarbon ambient. The p-SiCOH dielectric film has more —(CHx) and less Si—O—H and Si—H bonding moieties. Moreover, a stable pSiOCH dielectric film is provided in which the amount of Si—OH (silanol) and Si—H groups at least within the pores has been reduced by about 90% or less by the post treatment. A p-SiCOH dielectric film is produced that is flexible since the pores include stabilized crosslinking —(CH | 12-27-2012 |
20130009282 | MICROELECTRONIC STRUCTURE INCLUDING AIR GAP - A microelectronic structure and a method for fabricating the microelectronic structure provide a plurality of voids interposed between a plurality of conductor layers. The plurality of voids is also located between a liner layer and an inter-level dielectric layer. The voids provide for enhanced electrical performance of the microelectronic structure. | 01-10-2013 |
20130012017 | MICROELECTRONIC STRUCTURE INCLUDING AIR GAP - A microelectronic structure and a method for fabricating the microelectronic structure provide a plurality of voids interposed between a plurality of conductor layers. The plurality of voids is also located between a liner layer and an inter-level dielectric layer. The voids provide for enhanced electrical performance of the microelectronic structure. | 01-10-2013 |
20130087923 | MULTI COMPONENT DIELECTRIC LAYER - An in-situ process is described incorporating plasma enhanced chemical vapor deposition comprising flowing at least one of a Si, Si═C, B, Si═B, Si═B═C, and B═C containing precursor, and a N containing precursors at first times and removing the N precursor at second times and starting the flow of an oxidant gas and a porogen gas into the chamber. A dielectric layer is described comprising a network having inorganic random three dimensional covalent bonding throughout the network which contains at least one SiCN, SiCNH, SiN, SiNH, BN, BNH, CBN, CBNH, BSiN, BSiNH, SiCBN and SiCBNH as a first component and a low k dielectric as a second component adjacent thereto. | 04-11-2013 |
20130175697 | Interlevel Dielectric Stack for Interconnect Structures - A dielectric stack and method of depositing the stack to a substrate using a single step deposition process. The dielectric stack includes a dense layer and a porous layer of the same elemental compound with different compositional atomic percentage, density, and porosity. The stack enhances mechanical modulus strength and enhances oxidation and copper diffusion barrier properties. The dielectric stack has inorganic or hybrid inorganic-organic random three-dimensional covalent bonding throughout the network, which contain different regions of different chemical compositions such as a cap component adjacent to a low-k component of the same type of material but with higher porosity. | 07-11-2013 |
20130234260 | INTERCONNECT STRUCTURE FOR IMPROVED TIME DEPENDENT DIELECTRIC BREAKDOWN - The present disclosure provides a method of forming an interconnect to an electrical device. In one embodiment, the method of forming an interconnect includes providing a device layer on a substrate, wherein the device layer comprises at least one electrical device, an intralevel dielectric over the at least one electrical device, and a contact that is in electrical communication with the at least one electrical device. An interconnect metal layer is formed on the device layer, and a tantalum-containing etch mask is formed on a portion of the interconnect metal layer. The interconnect metal layer is etched to provide a trapezoid shaped interconnect in communication with the at least one electrical device. The trapezoid shaped interconnect has a first surface that is in contact with the device layer with a greater width than a second surface of the trapezoid shaped interconnect that is in contact with the tantalum-containing etch mask. | 09-12-2013 |
20140117457 | BEOL STRUCTURES INCORPORATING ACTIVE DEVICES AND MECHANICAL STRENGTH - An integrated circuit and method includes a substrate, a plurality of semiconductor device layers monolithically integrated on the substrate, and a metal wiring layer with vias interconnecting the plurality of semiconductor device layers. The semiconductor device layers are devoid of bonding or joining interface with the substrate. | 05-01-2014 |
20140120667 | BEOL STRUCTURES INCORPORATING ACTIVE DEVICES AND MECHANICAL STRENGTH - A method of fabricating a monolithic integrated circuit using a single substrate, the method including forming a first semiconductor layer from a substrate, fabricating semiconductor devices on the substrate, fabricating at least one metal wiring layer on the semiconductor devices, forming at least one dielectric layer in integral contact with the at least one metal wiring layer, forming contact openings through the at least one dielectric layer to expose regions of the at least one metal wiring layer, integrally forming, from the substrate, a second semiconductor layer on the dielectric layer, and in contact with the at least one metal wiring layer through the contact openings, and forming a plurality of non-linear semiconductor devices in said second semiconductor layer. | 05-01-2014 |
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 |
20140256154 | INTERLEVEL DIELECTRIC STACK FOR INTERCONNECT STRUCTURES - A dielectric stack and method of depositing the stack to a substrate using a single step deposition process. The dielectric stack includes a dense layer and a porous layer of the same elemental compound with different compositional atomic percentage, density, and porosity. The stack enhances mechanical modulus strength and enhances oxidation and copper diffusion barrier properties. The dielectric stack has inorganic or hybrid inorganic-organic random three-dimensional covalent bonding throughout the network, which contain different regions of different chemical compositions such as a cap component adjacent to a low-k component of the same type of material but with higher porosity. | 09-11-2014 |
20140284815 | INTERLEVEL DIELECTRIC STACK FOR INTERCONNECT STRUCTURES - A dielectric stack and method of depositing the stack to a substrate using a single step deposition process. The dielectric stack includes a dense layer and a porous layer of the same elemental compound with different compositional atomic percentage, density, and porosity. The stack enhances mechanical modulus strength and enhances oxidation and copper diffusion barrier properties. The dielectric stack has inorganic or hybrid inorganic-organic random three-dimensional covalent bonding throughout the network, which contain different regions of different chemical compositions such as a cap component adjacent to a low-k component of the same type of material but with higher porosity. | 09-25-2014 |