Abstract: High performance light emitting diode with vias. In accordance with a first embodiment of the present invention, an article of manufacture includes a light emitting diode. The light emitting diode includes a plurality of filled vias configured to connect a doped region on one side of the light emitting diode to a plurality of contacts on the other side of the light emitting diode. The filled vias may comprise less that 10% of a surface area of the light emitting diode.

Abstract: Apparatuses and methods are described. This apparatus includes a bridge die having first contacts on a die surface being in a molding layer of a reconstituted wafer. The reconstituted wafer has a wafer surface including a layer surface of the molding layer and the die surface. A redistribution layer on the wafer surface includes electrically conductive and dielectric layers to provide conductive routing and conductors. The conductors extend away from the die surface and are respectively coupled to the first contacts at bottom ends thereof. At least second and third IC dies respectively having second contacts on corresponding die surfaces thereof are interconnected to the bridge die and the redistribution layer. A first portion of the second contacts are interconnected to top ends of the conductors opposite the bottom ends thereof in part for alignment of the at least second and third IC dies to the bridge die.

Abstract: A device and method of forming the device that includes cavities formed in a substrate of a substrate device, the substrate device also including conductive vias formed in the substrate. Chip devices, wafers, and other substrate devices can be mounted to the substrate device. Encapsulation layers and materials may be formed over the substrate device in order to fill the cavities.

Abstract: A method of making an assembly can include juxtaposing a top surface of a first electrically conductive element at a first surface of a first substrate with a top surface of a second electrically conductive element at a major surface of a second substrate. One of: the top surface of the first conductive element can be recessed below the first surface, or the top surface of the second conductive element can be recessed below the major surface. Electrically conductive nanoparticles can be disposed between the top surfaces of the first and second conductive elements. The conductive nanoparticles can have long dimensions smaller than 100 nanometers. The method can also include elevating a temperature at least at interfaces of the juxtaposed first and second conductive elements to a joining temperature at which the conductive nanoparticles can cause metallurgical joints to form between the juxtaposed first and second conductive elements.

Abstract: Methods of forming flipped radio frequency (RF) filter components are provided. An example method for miniaturizing conventional planar RF filters comprises: determining radio frequency (RF) filtering characteristics of a conventional planar microstrip RF filter or a conventional stripline RF filter, determining distributed RF filter elements for emulating the RF filtering characteristics of the conventional planar microstrip RF filter or the conventional stripline RF filter, creating each distributed RF filter element on a substrate, laminating a stack of the distributed RF filter elements into a single solid RF filter module; and mounting the single solid RF filter module on a horizontal substrate to vertically dispose the distributed RF filter elements of the stack. The methods create laminated stacks of distributed RF filter elements that provide a dramatic reduction in size over the horizontal planar RF filters that they replace.

Abstract: A contact pad includes a solder-wettable porous network (310) which wicks the molten solder (130) and thus restricts the lateral spread of the solder, thus preventing solder bridging between adjacent contact pads.

Abstract: A method for simultaneously making a plurality of microelectronic packages by forming an electrically conductive redistribution structure along with a plurality of microelectronic element attachment regions on a carrier. The attachment regions being spaced apart from one another and overlying the carrier. The method also including the formation of conductive connector elements between adjacent attachment regions. Each connector element having the first or second end adjacent the carrier and the remaining end at a height of the microelectronic element. The method also includes forming an encapsulation over portions of the connector elements and subsequently singulating the assembly. into microelectronic units, each including a microelectronic element.

Abstract: In a microelectronic component having conductive vias (114) passing through a substrate (104) and protruding above the substrate, one or more conductive features (120E.A, 120E.B, or both) are provided above the substrate that wrap around the conductive vias' protrusions (114?) to form capacitors, electromagnetic shields, and possibly other elements. Other features and embodiments are also provided.

Abstract: Advanced flat metals for microelectronics are provided. While conventional processes create large damascene features that have a dishing defect that causes failure in bonded devices, example systems and methods described herein create large damascene features that are planar. In an implementation, an annealing process creates large grains or large metallic crystals of copper in large damascene cavities, while a thinner layer of copper over the field of a substrate anneals into smaller grains of copper. The large grains of copper in the damascene cavities resist dishing defects during chemical-mechanical planarization (CMP), resulting in very flat damascene features. In an implementation, layers of resist and layers of a second coating material may be applied in various ways to resist dishing during chemical-mechanical planarization (CMP), resulting in very flat damascene features.

Abstract: Methods and apparatuses for stacking devices in an integrated circuit assembly are provided. A tray for supporting multiple dies of a semiconductor material enables both top side processing and bottom side processing of the dies. The dies can be picked and placed for bonding on a substrate or on die stacks without flipping the dies, thereby avoiding particulate debris from the diced edges of the dies from interfering and contaminating the bonding process. In an implementation, a liftoff apparatus directs a pneumatic flow of gas to lift the dies from the tray for bonding to a substrate, and to previously bonded dies, without flipping the dies. An example system allows processing of both top and bottom surfaces of the dies in a single cycle in preparation for bonding, and then pneumatically lifts the dies up to a target substrate so that top sides of the dies bond to bottom sides of dies of the previous batch, in an efficient and flip-free assembly of die stacks.

Abstract: Systems and methods for providing 3D wafer assembly with known-good-dies are provided. An example method compiles an index of dies on a semiconductor wafer and removes the defective dies to provide a wafer with dies that are all operational. Defective dies on multiple wafers may be removed in parallel, and resulting wafers with all good dies stacked in 3D wafer assembly. In an implementation, the spaces left by removed defective dies may be filled at least in part with operational dies or with a fill material. Defective dies may be replaced either before or after wafer-to-wafer assembly to eliminate production of defective stacked devices, or the spaces may be left empty. A bottom device wafer may also have its defective dies removed or replaced, resulting in wafer-to-wafer assembly that provides 3D stacks with no defective dies.

Abstract: Embedded organic interposers for high bandwidth are provided. Example embedded organic interposers provide thick conductors with more dielectric space, and more routing layers of such conductors than conventional interposers, in order to provide high bandwidth transmission capacity over longer spans. The embedded organic interposers provide high bandwidth transmission paths between components such as HBM, HBM2, and HBM3 memory stacks, and other components. To provide the thick conductors and more routing layers for greater transmission capacity, extra space is achieved by embedding the organic interposers in the core of the package. Example embedded organic interposers lower a resistive-capacitive (RC) load of the routing layers to provide an improved data transfer rate of 1 gigabits per second over at least a 6 mm span, for example. The embedded interposers are not limited to use with memory modules.

Abstract: A method for making a microelectronic unit includes forming a plurality of wire bonds on a first surface in the form of a conductive bonding surface of a structure comprising a patternable metallic element. The wire bonds are formed having bases joined to the first surface and end surfaces remote from the first surface. The wire bonds have edge surfaces extending between the bases and the end surfaces. The method also includes forming a dielectric encapsulation layer over a portion of the first surface of the conductive layer and over portions of the wire bonds such that unencapsulated portions of the wire bonds are defined by end surfaces or portions of the edge surfaces that are uncovered by the encapsulation layer. The metallic element is patterned to form first conductive elements beneath the wire bonds and insulated from one another by portions of the encapsulation layer.

Abstract: A three-dimensional stacking technique performed in a wafer-to-wafer fashion reducing the machine movement in production. The Wafers are processed with metallic traces and stacked before dicing into separate die stacks. The traces of each layer of the stacks are interconnected via electroless plating.

Abstract: Apparatus and method relating generally to an LED display is disclosed. In such an apparatus, a driver die has a plurality of driver circuits. A plurality of light-emitting diodes, each having a thickness of 10 microns or less and discrete with respect to one another, are respectively interconnected to the plurality of driver circuits. The plurality of light-emitting diodes includes a first portion for a first color, a second portion for a second color, and a third portion for a third color respectively obtained from a first, a second, and a third optical wafer. The first, the second, and the third color are different from one another.

Abstract: Apparatuses relating generally to a vertically integrated microelectronic package are disclosed. In an apparatus thereof, a substrate has an upper surface and a lower surface opposite the upper surface. A first microelectronic device is coupled to the upper surface of the substrate. The first microelectronic device is a passive microelectronic device. First wire bond wires are coupled to and extend away from the upper surface of the substrate. Second wire bond wires are coupled to and extend away from an upper surface of the first microelectronic device. The second wire bond wires are shorter than the first wire bond wires. A second microelectronic device is coupled to upper ends of the first wire bond wires and the second wire bond wires. The second microelectronic device is located above the first microelectronic device and at least partially overlaps the first microelectronic device.

Abstract: In a multi-chip module (MCM), a “super” chip (110N) is attached to multiple “plain” chips (110F? “super” and “plain” chips can be any chips). The super chip is positioned above the wiring board (WB) but below at least some of plain chips (110F). The plain chips overlap the super chip. Further, the plain chips' low speed IOs can be connected to the WB by long direct connections such as bond wires (e.g. BVAs) or solder stacks; such connections can be placed side by side with the super chip. Such connections can be long, so the super chip is not required to be thin. Also, if through-substrate vias (TSVs) are omitted, the manufacturing yield is high and the manufacturing cost is low. Other structures are provided that combine the short and long direct connections to obtain desired physical and electrical properties.

Abstract: An apparatus relating generally to a substrate is disclosed. In this apparatus, a post extends from the substrate. The post includes a conductor member. An upper portion of the post extends above an upper surface of the substrate. An exterior surface of the post associated with the upper portion is in contact with a dielectric layer. The dielectric layer is disposed on the upper surface of the substrate and adjacent to the post to provide a dielectric collar for the post. An exterior surface of the dielectric collar is in contact with a conductor layer. The conductor layer is disposed adjacent to the dielectric collar to provide a metal collar for the post, where a top surface of each of the conductor member, the dielectric collar and the metal collar have formed thereon a bond structure for interconnection of the metal collar and the conductor member.

Abstract: Representative implementations of devices and techniques provide reinforcement for a carrier or a package. A reinforcement layer is added to a surface of the carrier, often a bottom surface of the carrier that is generally under-utilized except for placement of terminal connections. The reinforcement layer adds structural support to the carrier or package, which can be very thin otherwise. In various embodiments, the addition of the reinforcement layer to the carrier or package reduces warpage of the carrier or package.

Abstract: Methods of forming a back side image sensor device, as well as back side image sensor devices formed, are disclosed. In one such a method, an image sensor wafer having a first dielectric layer with a first surface is obtained. A reconstituted wafer having a processor die and a second dielectric layer with a second surface is obtained. The reconstituted wafer and the image sensor wafer are bonded to one another including coupling the first surface of the first dielectric layer and the second surface of the second dielectric layer. In another method, such formation is for a processor die bonded to an image sensor wafer. In yet another method, such formation is for a processor die bonded to an image sensor die.