Patent application number | Description | Published |
20080248643 | SOLDER CONNECTOR STRUCTURE AND METHOD - Disclosed are embodiments of a far back end of the line solder connector and a method of forming the connector that eliminates the use aluminum, protects the integrity of the ball limiting metallurgy (BLM) layers and promotes adhesion of the BLM layers by incorporating a thin conformal conductive liner into the solder connector structure. This conductive liner coats the top of the via filling in any divots in order to create a uniform surface for BLM deposition and to, thereby, protect the integrity of the BLM layers. The liner further coats the dielectric sidewalls of the well in which the BLM layers are formed in order to enhance adhesion of the BLM layers to the well. | 10-09-2008 |
20080306797 | METHOD AND SYSTEM FOR AUTOMATED RESOURCE MANAGEMENT AND OPTIMIZATION - A method for automated resource management and optimization, the method includes: monitoring one or more of the following: resource usage, level of resource utilization, and resource amenities; receiving a request for reserving a resource; determining whether the request for the resource is granted as originally requested; wherein the determining of whether to grant the request for resources as originally requested is based one or more thresholds and conditions; wherein the one or more thresholds and conditions are based on the monitoring of at least one of the following: resource usage, the level of resource utilization; and resource amenities; and wherein if the request for reserving a resource fails to meet the one or more thresholds and conditions the request is either denied or modified. | 12-11-2008 |
20080319565 | SYSTEM AND METHODS FOR MANAGING PROCESS FLOW CHANGES - A computer program product for performing automated error checking in an automated production line, includes instructions for: receiving change information for changing a production process; comparing the change information to standard information for the production process; and reporting information from the comparing. Manufacturing execution software and a system for employing the manufacturing execution software are provided. | 12-25-2008 |
20090019691 | MICRO-ELECTROMECHANICAL SUB-ASSEMBLY HAVING AN ON-CHIP TRANSFER MECHANISM | 01-22-2009 |
20090181532 | INTEGRATION SCHEME FOR EXTENSION OF VIA OPENING DEPTH - An interconnect structure having an incomplete via opening is processed to deepen a via opening and to expose a metal line. In case the interconnect structure comprises a metal pad or a blanket metal layer, the metal pad or the metal layer is removed selective to an underlying dielectric layer to expose the incomplete via opening. Another dielectric layer is formed within the incomplete via opening to compensated for differences in the total dielectric thickness above the metal line relative to an optimal dielectric stack. A photoresist is applied thereupon and patterned. An anisotropic etch process for formation of a normal via opening may be employed with no or minimal modification to form a proper via opening and to expose the metal line. A metal pad is formed upon the metal line so that electrical contact is provided between the metal pad and the metal line. | 07-16-2009 |
20100047990 | METHOD OF FABRICATING A HIGH Q FACTOR INTEGRATED CIRCUIT INDUCTOR - A method of forming an inductor. The method including: (a) forming a dielectric layer on a top surface of a substrate; after (a), (b) forming a lower trench in the dielectric layer; after (b), (c) forming a resist layer on a top surface of the dielectric layer; after (c), (d) forming an upper trench in the resist layer, the upper trench aligned to the lower trench, a bottom of the upper trench open to the lower trench; and after (d), (e) completely filling the lower trench and at least partially filling the upper trench with a conductor in order to form the inductor. | 02-25-2010 |
20110095435 | COAXIAL THROUGH-SILICON VIA - A through-silicon via (TSV) structure forming a unique coaxial or triaxial interconnect within the silicon substrate. The TSV structure is provided with two or more independent electrical conductors insulated from another and from the substrate. The electrical conductors can be connected to different voltages or ground, making it possible to operate the TSV structure as a coaxial or triaxial device. Multiple layers using various insulator materials can be used as insulator, wherein the layers are selected based on dielectric properties, fill properties, interfacial adhesion, CTE match, and the like. The TSV structure overcomes defects in the outer insulation layer that may lead to leakage. A method of fabricating such a TSV structure is also described. | 04-28-2011 |
20110175216 | INTEGRATED VOID FILL FOR THROUGH SILICON VIA - A microelectronic assembly and related method of forming a through hole extending through a first wafer and a second wafer are provided. The first and second wafer have confronting faces and metallic features at the faces which are joined together to assemble the first and second wafers. A hole can be etched downwardly through the first wafer until a gap is partially exposed between the confronting faces of the first and second wafers. The hole can have a first wall extending in a vertical direction, and a second wall sloping inwardly from the first wall to an inner opening through which the interfacial gap is exposed. Material of the first or second wafers exposed within the hole can then be sputtered such that at least some of the sputtered material deposits onto at least one of the exposed confronting faces of the first and second wafers and provides a wall between the confronting faces. The method can include resuming etching the hole so as to extend the first wall fully through the first wafer, the wall between the wafers and into the second wafer, such that the wall of the hole extends continuously from the first wafer into the second wafer. An electrically conductive through silicon via can then be formed extending through the first wafer, the wall between the wafers and into the second wafer. | 07-21-2011 |
20110237026 | METHOD OF FORMING A MULTI-CHIP STACKED STRUCTURE INCLUDING A THIN INTERPOSER CHIP HAVING A FACE-TO-BACK BONDING WITH ANOTHER CHIP - A temporary substrate having an array of first solder pads is bonded to the front side of a first substrate by reflowing an array of first solder balls. The first substrate is thinned by removing the back side, and an array of second solder pads is formed on the back side surface of the first substrate. The assembly of the first substrate and the temporary substrate is diced to form a plurality of stacks, each including an assembly of a first semiconductor chip and a handle portion. A second semiconductor chip is bonded to an assembly through an array of the second solder balls. The handle portion is removed from each assembly by reflowing the array of the first solder balls, while the array of the second solder balls does not reflow. The assembly is subsequently mounted on a packaging substrate employing the array of the first solder balls. | 09-29-2011 |
20120018851 | METAL-CONTAMINATION-FREE THROUGH-SUBSTRATE VIA STRUCTURE - A through-substrate via (TSV) structure that is immune to metal contamination due to a backside planarization process is provided. After forming a through-substrate via (TSV) trench, a diffusion barrier liner is conformally deposited on the sidewalls of the TSV trench. A dielectric liner is formed by depositing a dielectric material on vertical portions of the diffusion barrier liner. A metallic conductive via structure is formed by subsequently filling the TSV trench. Horizontal portions of the diffusion barrier liner are removed. The diffusion barrier liner protects the semiconductor material of the substrate during the backside planarization by blocking residual metallic material originating from the metallic conductive via structure from entering into the semiconductor material of the substrate, thereby protecting the semiconductor devices within the substrate from metallic contamination. | 01-26-2012 |
20120146682 | YIELD ENHANCEMENT FOR STACKED CHIPS THROUGH ROTATIONALLY-CONNECTING-INTERPOSER - A set of first substrate and second substrate are manufactured with a built-in N-fold rotational symmetry around the center axis of each substrate, wherein N is an integer greater than 1. A set of N different interposers is provided such that an i-th interposer provides electrical connection between the first substrate and the second substrate with a rotational angle of (i−1)/N×2π. The first and second substrates are tested with each of the N different interposers therebetween. Once the rotational angle that provides the highest stacked chip yield is determined, the first and the second substrates can be bonded with an azimuthal rotation that provides the highest stacked chip yield. | 06-14-2012 |
20120175789 | ALIGNMENT MARKS TO ENABLE 3D INTEGRATION - Disclosed are a structure including alignment marks and a method of forming alignment marks in three dimensional (3D) structures. The method includes forming apertures in a first surface of a first semiconductor substrate; joining the first surface of the first semiconductor substrate to a first surface of a second semiconductor substrate; thinning the first semiconductor on a second surface of the first semiconductor substrate to provide optical contrast between the apertures and the first semiconductor substrate; and aligning a feature on the second surface of the first semiconductor substrate using the apertures as at least one alignment mark. | 07-12-2012 |
20120207920 | PROTECTING A MOLD HAVING A SUBSTANTIALLY PLANAR SURFACE PROVIDED WITH A PLURALITY OF MOLD CAVITIES - A method of protecting a mold having at least one substantially planar surface provided with a plurality of mold cavities includes inserting a plurality of mandrels into respective ones of the plurality of mold cavities, depositing a layer of mold protection material onto the at least one substantially planar surface and the plurality of mandrels, and removing the plurality of mandrels from the mold substrate. | 08-16-2012 |
20120258589 | METHOD OF FABRICATING COAXIAL THROUGH-SILICON VIA - A method of fabricating a through-silicon via (TSV) structure forming a unique coaxial or triaxial interconnect within the silicon substrate. The TSV structure is provided with two or more independent electrical conductors insulated from another and from the substrate. The electrical conductors can be connected to different voltages or ground, making it possible to operate the TSV structure as a coaxial or triaxial device. Multiple layers using various insulator materials can be used as insulator, wherein the layers are selected based on dielectric properties, fill properties, interfacial adhesion, CTE match, and the like. The TSV structure overcomes defects in the outer insulation layer that may lead to leakage. | 10-11-2012 |
20120292786 | INTEGRATED VOID FILL FOR THROUGH SILICON VIA - A microelectronic assembly having a through hole extending through a first wafer (or chip) and a second wafer (or chip) are provided. The first and second wafers (or chips) have confronting faces and metallic features at the faces which are joined together to assemble the first and second wafers (or chips) leaving a gap between the confronting faces. A hole is etched in the first wafer (or chip), then material is sputtered to form a wall of material in the gap between wafers (or chips). Etching continues to extend the hole into or through the second wafer (or chip). The hole is filled to form a substantially vertical through silicon conductive via. | 11-22-2012 |
20120326309 | OPTIMIZED ANNULAR COPPER TSV - The present disclosure provides a thermo-mechanically reliable copper TSV and a technique to form such TSV during BEOL processing. The TSV constitutes an annular trench which extends through the semiconductor substrate. The substrate defines the inner and outer sidewalls of the trench, which sidewalls are separated by a distance within the range of 5 to 10 microns. A conductive path comprising copper or a copper alloy extends within said trench from an upper surface of said first dielectric layer through said substrate. The substrate thickness can be 60 microns or less. A dielectric layer having interconnect metallization conductively connected to the conductive path is formed directly over said annular trench. | 12-27-2012 |
20130026606 | TSV PILLAR AS AN INTERCONNECTING STRUCTURE - The present invention includes embodiments of a processing method, and resulting structure, for building a chip having a TSV pillar which can be used as an interconnecting structure. The process includes the deposition of a dual diffusion barrier between the TSV and the substrate the TSV is embedded within. The TSV is then exposed from the back side of the substrate so that at least a portion of the TSV protrudes from the substrate and can be used as a contact for connecting the chip to another surface. The resulting TSV is rigid, highly conductive, can be placed in a tightly pitched grid of contacts, and reduces effects of CTE mismatch. | 01-31-2013 |
20130122702 | INTEGRATED VOID FILL FOR THROUGH SILICON VIA - A microelectronic assembly and related method of forming a through hole extending through a first chip and a second chip are provided. The first and second chip have confronting faces, metallic features join the first and second chips leaving a gap chips . A first etch creates a hole through the first chip. The hole has a first wall extending in a vertical direction, and a second wall sloping inwardly from the first wall to an inner opening to expose the gap. Material of the first or second chips exposed within the hole is sputtered to form a wall in the gap. A second etch extends the hole into the second chip. An electrically conductive through silicon via can then be formed extending through the first chip, the wall between the chips and into the second chip. | 05-16-2013 |
20130143400 | METAL-CONTAMINATION-FREE THROUGH-SUBSTRATE VIA STRUCTURE - A through-substrate via (TSV) structure that is immune to metal contamination due to a backside planarization process is provided. After forming a through-substrate via (TSV) trench, a diffusion barrier liner is conformally deposited on the sidewalls of the TSV trench. A dielectric liner is formed by depositing a dielectric material on vertical portions of the diffusion barrier liner. A metallic conductive via structure is formed by subsequently filling the TSV trench. Horizontal portions of the diffusion barrier liner are removed. The diffusion barrier liner protects the semiconductor material of the substrate during the backside planarization by blocking residual metallic material originating from the metallic conductive via structure from entering into the semiconductor material of the substrate, thereby protecting the semiconductor devices within the substrate from metallic contamination. | 06-06-2013 |
20130244420 | OPTIMIZED ANNULAR COPPER TSV - The present disclosure provides a thermo-mechanically reliable copper TSV and a technique to form such TSV during BEOL processing. The TSV constitutes an annular trench which extends through the semiconductor substrate. The substrate defines the inner and outer sidewalls of the trench, which sidewalls are separated by a distance within the range of 5 to 10 microns. A conductive path comprising copper or a copper alloy extends within said trench from an upper surface of said first dielectric layer through said substrate. The substrate thickness can be 60 microns or less. A dielectric layer having interconnect metallization conductively connected to the conductive path is formed directly over said annular trench. | 09-19-2013 |
20140035109 | METHOD AND STRUCTURE OF FORMING BACKSIDE THROUGH SILICON VIA CONNECTIONS - A method, and the resulting structure, to make a thinned substrate with backside redistribution wiring connected to through silicon vias of varying height. The method includes thinning a backside of a substrate to expose through silicon vias. Then a thick insulator stack, including an etch stop layer, is deposited and planarized. With a planar insulating surface in place, openings in the insulator stack can be formed by etching. The etch stop layer in the dielectric stack accommodates the differing heights vias. The etch stop is removed and a conductor having a liner is formed in the opening. The method gives a unique structure in which a liner around the bottom of the through silicon via remains in tact. Thus, the liner of the via and a liner of the conductor meet to form a double liner at the via/conductor junction. | 02-06-2014 |
20140061915 | PREVENTION OF THRU-SUBSTRATE VIA PISTONING USING HIGHLY DOPED COPPER ALLOY SEED LAYER - A method of forming an integrated circuit device includes forming a diffusion barrier layer in an opening defined in a substrate; forming a highly doped copper alloy seed layer over the diffusion barrier layer, the copper alloy seed layer having a minority alloy component having a concentration greater than 0.5% atomic; and forming a copper layer over the copper alloy seed layer so as to define a wiring structure of the integrated circuit device. | 03-06-2014 |
20140124946 | ENHANCED CAPTURE PADS FOR THROUGH SEMICONDUCTOR VIAS - Method of forming a capture pad on a semiconductor substrate. The method includes providing a semiconductor substrate having an active side and an inactive side and having a plurality of unfilled TSVs extending between the active side and the inactive side; filling the TSVs with a metal such that the metal is recessed with respect to at least one of the active side and the inactive side and does not entirely fill the TSVs; defining capture pad areas on the at least one of the active side and inactive side adjacent to the recessed TSVs; filling the capture pad areas and recessed TSVs with the same metal to form a capture pad in direct contact with each of the TSVs, each of the capture pads having an all metal portion that follows an outline of each of the TSVs. Also disclosed is a semiconductor substrate having a capture pad. | 05-08-2014 |
20140124954 | METHOD AND STRUCTURE OF FORMING BACKSIDE THROUGH SILICON VIA CONNECTIONS - A method, and the resulting structure, to make a thinned substrate with backside redistribution wiring connected to through silicon vias of varying height. The method includes thinning a backside of a substrate to expose through silicon vias. Then a thick insulator stack, including an etch stop layer, is deposited and planarized. With a planar insulating surface in place, openings in the insulator stack can be formed by etching. The etch stop layer in the dielectric stack accommodates the differing heights vias. The etch stop is removed and a conductor having a liner is formed in the opening. The method gives a unique structure in which a liner around the bottom of the through silicon via remains in tact. Thus, the liner of the via and a liner of the conductor meet to form a double liner at the via/conductor junction. | 05-08-2014 |
20140127904 | ENHANCED CAPTURE PADS FOR THROUGH SEMICONDUCTOR VIAS - Method of forming a capture pad on a semiconductor substrate. The method includes providing a semiconductor substrate having an active side and an inactive side and having a plurality of unfilled TSVs extending between the active side and the inactive side; filling the TSVs with a metal; defining capture pad areas on at least one of the active side and the inactive side adjacent to the TSVs, the defined capture pad areas comprising insulator islands and open areas; filling the open areas with the same metal to form a capture pad in direct contact with each of the TSVs, each of the capture pads having an all metal portion that follows an outline of each of the TSVs. | 05-08-2014 |