Abstract: Embodiments of the present disclosure are directed toward formation of solder and copper interconnect structures and associated techniques and configurations. In one embodiment, a method includes providing an integrated circuit (IC) substrate and depositing a solderable material on the IC substrate using an ink deposition process, a binder printing system, or a powder laser sintering system. In another embodiment, a method includes providing an integrated circuit (IC) substrate and depositing a copper powder on the IC substrate using an additive process to form a copper interconnect structure. Other embodiments may be described and/or claimed.

Abstract: A method for forming a chip package is provided. The method includes providing a first substrate and a second substrate. The first substrate is attached onto the second substrate by an adhesive layer. A first opening is formed to penetrate the first substrate and the adhesive layer and separate the first substrate and the adhesive layer into portions. A chip package formed by the method is also provided.

Abstract: A method of manufacturing through silicon via stacked structures. A plurality of substrates is provided. At least one tapered hole is formed on one surface of each substrate. Each tapered hole is filled up with a tapered through silicon via. A recessed portion is formed on the wider end of each tapered through silicon via. A part of the substrate is removed until the narrower end of each tapered through silicon via protrudes from the other surface of the substrate. The substrates is stacked one after another by fitting and jointing the narrower end of each tapered through silicon via on one substrate into a corresponding recessed portion of the tapered through silicon via of another substrate.

Abstract: A method of forming conductive traces on insulated substrate includes the steps of providing an insulated substrate; forming a coating layer on a surface of the insulated substrate, dividing the coating layer into traces-forming zones and non-traces-forming zones through laser engraving, and removing areas of the coating layer that are located in the traces-forming zones through laser-vaporizing to expose corresponding portions of the surface of the insulated substrate; forming a metallized layer of conductive traces by performing a metallizing treatment on the exposed portions of the insulated substrate and on the coating layer; and directly stripping off the residual coating layer from the non-traces-forming zones or removing it using an acid, an alkaline or a neutral solution.

Abstract: A tape capable of laser ablation may be used in the formation of microelectronic interconnects, wherein the tape may be attached to bond pads on a microelectronic device and vias may be formed by laser ablation through the tape to expose at least a portion of corresponding bond pads. The microelectronic interconnects may be formed on the bond pads within the vias, such as by solder paste printing and solder reflow. The laser ablation tape can be removed after the formation of the microelectronic interconnects.

Abstract: A device includes a tube extending in a longitudinal direction and a hollow channel arranged in the tube. An end part of the tube is formed such that first electromagnetic radiation paths extending in the tube and outside of the hollow channel in the longitudinal direction are focused in a first focus.

Abstract: A method is provided for imaging a region of interest. The method includes defining a lamella within a microelectronic device, where the region of interest is in the lamella. The lamella has a first and second surface, and a first sacrificial layer contacts the first surface. The region of interest includes a material of interest, and an imaging technique capable of detecting the material of interest is selected. A support layer is formed on the second surface, where the support layer is transparent to the imaging technique. The first sacrificial layer is removed, and an image of the region of interest is produced.

Abstract: A MEMS device (20) with stress isolation includes elements (28, 30, 32) formed in a first structural layer (24) and elements (68, 70) formed in a second structural layer (26), with the layer (26) being spaced apart from the first structural layer (24). Fabrication methodology (80) entails forming (92, 94, 104) junctions (72, 74) between the layers (24, 26). The junctions (72, 74) connect corresponding elements (30, 32) of the first layer (24) with elements (68, 70) of the second layer (26). The fabrication methodology (80) further entails releasing the structural layers (24, 26) from an underlying substrate (22) so that all of the elements (30, 32, 68, 70) are suspended above the substrate (22) of the MEMS device (20), wherein attachment of the elements (30, 32, 68, 70) with the substrate (22) occurs only at a central area (46) of the substrate (22).

Abstract: An ion implantation system and method, providing cooling of dopant gas in the dopant gas feed line, to combat heating and decomposition of the dopant gas by arc chamber heat generation, e.g., using boron source materials such as B2F4 or other alternatives to BF3. Various arc chamber thermal management arrangements are described, as well as modification of plasma properties, specific flow arrangements, cleaning processes, power management, eqillibrium shifting, optimization of extraction optics, detection of deposits in flow passages, and source life optimization, to achieve efficient operation of the ion implantation system.

Abstract: A semiconductor device which can prevent a deterioration in the electrical properties by preventing sputters generated by laser welding from adhering to a circuit pattern or a semiconductor chip and a method for fabricating such a semiconductor device are provided. A connection conductor is bonded to a copper foil formed over a ceramic by a solder and resin is injected to a level lower than a top of the connection conductor. Laser welding is then performed. After that, resin is injected. This prevents sputters generated by the laser welding from adhering to a circuit pattern or a semiconductor chip. As a result, a deterioration in the electrical properties can be prevented.

Abstract: A three-dimensional integrateds circuit structure includes a first metal circuit substrate, an interposer substrate disposed on the first metal circuit substrate and electrically connected therewith, and at least one semiconductor component disposed on the interposer substrate. The interposer substrate is used to dissipate the heat generated by the operation of the semiconductor components, so as to achieve the objective of increasing the lifespan of the semiconductor components.

Abstract: An embedded semiconductor die package is made by mounting a frame carrier to a temporary carrier with an adhesive. The frame carrier includes die mounting sites each including a leadframe interconnect structure around a cavity. A semiconductor die is disposed in each cavity. An encapsulant is deposited in the cavity over the die. A package interconnect structure is formed over the leadframe interconnect structure and encapsulant. The package interconnect structure and leadframe interconnect structure are electrically connected to the die. The frame carrier is singulated into individual embedded die packages. The semiconductor die can be vertically stacked or placed side-by-side within the cavity. The embedded die packages can be stacked and electrically interconnected through the leadframe interconnect structure. A semiconductor device can be mounted to the embedded die package and electrically connected to the die through the leadframe interconnect structure.

Abstract: A layer of a mask material is deposited on a substrate. A beam of energy is scanned across the mask material in a rasterized linear pattern and in accordance with a scan pitch that is based on a pitch of conductive structure segments to be formed on the substrate. The beam of energy is defined to transform the mask material upon which the beam of energy is incident into a removable state. During scanning the beam of energy across the mask material, the beam of energy is turned on at locations where a conductive structure is to be formed on the substrate, and the beam of energy is turned off at locations where a conductive structure is not to be formed on the substrate.

Abstract: A method of manufacture of an integrated circuit packaging system includes: providing a substrate; mounting a top integrated circuit on a first side of the substrate; mounting a bottom integrated circuit on a second side of the substrate; forming a top encapsulation over the top integrated circuit and a bottom encapsulation over the bottom integrated circuit simultaneously; and forming a bottom via through the bottom encapsulation to the substrate.

Abstract: A wiring board includes a stacked body having a plurality of insulating layers and a plurality of wiring layers which are alternately stacked, and a solder-resist layer being formed on one side of the stacked body and covering the wiring layer exposed to the one side of the stacked body. The insulating layer is exposed to the other side of the stacked body. The solder-resist layer is in a transparent or semitransparent light yellow color.

Abstract: Systems and methods are disclosed for performing laser annealing in a manner that reduces or minimizes wafer surface temperature variations during the laser annealing process. The systems and methods include annealing the wafer surface with first and second laser beams that represent preheat and anneal laser beams having respective first and second intensities. The preheat laser beam brings the wafer surface temperate close to the annealing temperature and the anneal laser beam brings the wafer surface temperature up to the annealing temperature. The anneal laser beam can have a different wavelength, or the same wavelength but different orientation relative to the wafer surface. Reflectivity maps of the wafer surface at the preheat and anneal wavelengths are measured and used to select first and second intensities that ensure good anneal temperature uniformity as a function of wafer position.

Abstract: A method of manufacture of an integrated circuit packaging system includes: providing a routable layer having a column; mounting an integrated circuit structure in direct contact with the column; and forming a gamma connector to electrically connect the column to the integrated circuit structure.

Abstract: A semiconductor substrate is irradiated with accelerated hydrogen ions, thereby forming a damaged region including a large amount of hydrogen. After a single crystal semiconductor substrate and a supporting substrate are bonded to each other, the semiconductor substrate is heated, so that the single crystal semiconductor substrate is separated in the damaged region. A single crystal semiconductor layer which is separated from the single crystal semiconductor substrate is irradiated with a laser beam. The single crystal semiconductor layer is melted by laser beam irradiation, whereby the single crystal semiconductor layer is recrystallized to recover its crystallinity and to planarized a surface of the single crystal semiconductor layer. After the laser beam irradiation, the single crystal semiconductor layer is heated at a temperature at which the single crystal semiconductor layer is not melted, so that the lifetime of the single crystal semiconductor layer is improved.

Abstract: A laser absorption layer is first selectively formed in a seal pattern region surrounding an array of electromechanical systems elements, followed by depositing an antistiction layer as a blanket layer over the substrate and the laser absorption layer. The antistiction layer is then selectively removed from the seal pattern using a laser. An epoxy sealing material is provided in the seal pattern where the antistiction layer was removed and a backplate is sealed to the substrate using epoxy.

Abstract: A substrate table used for manufacturing a chip is provided. The substrate table includes a substrate stage, a substrate placement surface formed on the substrate stage, and on which a substrate is placed, and a guiding member that can project and retract from the substrate placement surface. The guiding member positions the substrate when the guiding member is at a projected position abutting an edge portion of the substrate placed on the substrate placement surface, and the guiding member retracts at a time of applying a tape to the substrate.

Abstract: A method and device for alternatively contacting two wafer-like component composite arrangements, in which two component composite arrangements, provided with contact metallizations on their opposing contact surfaces, are brought into a coverage position with their contact metallizations to form contact pairs, in which position the contact metallizations to be joined together are pressed against one another, the contact metallizations being contacted by exposing the rear of one of the component composite arrangements to laser radiation, the wavelength of the laser radiation being selected as a function of the degree of absorption of the component composite arrangement, so that a transmission of the laser radiation through the component composite arrangement exposed to the laser radiation at the rear is essentially suppressed or an absorption of the laser radiation takes place essentially in the contact metallizations of one or both component composite arrangements.

Abstract: A method of manufacture of an integrated circuit packaging system includes: providing an integrated circuit having an active side and a non-active side; forming a channel through the integrated circuit; forming an indent, having a flange and an indent side, from a peripheral region of the non-active side; and forming a conformal interconnect, having an offset segment, a sloped segment, and a flange segment, under the indent.

Abstract: A method is provided for detecting laser optical paths in integrated circuit (IC) packages. The method provides an IC die encapsulated as a package in a compound of glass spheres and epoxy. Power is supplied to the IC. The IC is scanned with a laser. Typically, a laser wavelength is used that is minimally absorbed by the glass spheres in the epoxy compound of the IC package, and changes in current to the IC are detected. A detected current change is cross-referenced against a scanned IC package surface region. This process identifies an optical pathway underlying the scanned IC package surface region. In some aspects, this process leads to the identification of a glass sphere-collecting package structure underlying the optical pathway. Examples of a glass sphere-collecting structure might include an inner lead wire, lead frame edge, or die edge.

Abstract: An embedded semiconductor die package is made by mounting a frame carrier to a temporary carrier with an adhesive. The frame carrier includes die mounting sites each having a leadframe interconnect structure around a cavity. A semiconductor die is disposed in each cavity. An encapsulant is deposited in the cavity over the die. A package interconnect structure is formed over the leadframe interconnect structure and encapsulant. The package interconnect structure and leadframe interconnect structure are electrically connected to the die. The frame carrier is singulated into individual embedded die packages. The semiconductor die can be vertically stacked or placed side-by-side within the cavity. The embedded die packages can be stacked and electrically interconnected through the leadframe interconnect structure. A semiconductor device can be mounted to the embedded die package and electrically connected to the die through the leadframe interconnect structure.

Abstract: It is an object to improve a yield of a step of cutting off a substrate. A substrate is cut off by using an ablation process. An ablation process uses a phenomenon in which a molecular bond in a portion irradiated with a laser beam, that is, a portion which absorbs the laser beam is cut off, photodegraded, and evaporated. In other words, a substrate is irradiated with a laser beam, a molecular bond in a portion of the substrate is cut off, photodegraded, and evaporated; accordingly, a groove is formed in the substrate. A method for cutting the substrate has steps of selectively emitting a laser beam and forming a groove in the substrate, and selectively emitting a laser beam to the groove and cutting off the substrate. Methods for manufacturing a groove in a substrate and cutting off a substrate are used for manufacturing a semiconductor device.

Abstract: A method and device for alternatively contacting two wafer-like component composite arrangements, in which two component composite arrangements, provided with contact metallizations on their opposing contact surfaces, are brought into a coverage position with their contact metallizations to form contact pairs, in which position the contact metallizations to be joined together are pressed against one another, the contact metalllizations being contacted by exposing the rear of one of the component composite arrangements to laser radiation, the wavelength of the laser radiation being selected as a function of the degree of absorption of the component composite arrangement, so that a transmission of the laser radiation through the component composite arrangement exposed to the laser radiation at the rear is essentially suppressed or an absorption of the laser radiation takes place essentially in the contact metallizations of one or both component composite arrangements.

Abstract: A method for manufacturing a semiconductor device including covering a portion of at least one semiconductor device with a foil, including covering at least one target region of the semiconductor device, and illuminating the foil with a laser to singulate from the foil a portion covering the at least one target region of the at least one semiconductor device.

Abstract: A laser annealing process for recovering crystallinity of a deposited semiconductor film such as of silicon which had undergone morphological damage, said process comprising activating the semiconductor by irradiating a pulsed laser beam operating at a wavelength of 400 nm or less and at a pulse width of 50 nsec or less onto the surface of the film, wherein, said deposited film is coated with a transparent film such as a silicon oxide film at a thickness of from 3 to 300 nm, and the laser beam incident to said coating is applied at an energy density E (mJ/cm2) provided that it satisfies the relation: log10 N??0.02(E?350), where N is the number of shots of the pulsed laser beam.

Abstract: A metal layer is formed on an upper surface of a resin layer provided to cover a plurality of semiconductor chips at a side on which an internal connecting terminal is disposed and the internal connecting terminal, and the metal layer is pressed to cause the metal layer in a corresponding portion to a wiring pattern to come in contact with the internal connecting terminal, and to then bond the metal layer in a portion provided in contact with the internal connecting terminal to the internal connecting terminal in a portion provided in contact with the metal layer.

Abstract: An apparatus for supplying electrical power to a movable member. The apparatus includes a fixed member, the movable member moving relative to the fixed member, a flexible wiring member having an end connected to the movable member and another end connected to the fixed member, configured to transmit the electrical power from the fixed member to the movable member, and a cooling member configured to cool the fixed member.

Abstract: A method of manufacturing a semiconductor device includes preparing a substrate on which a fuze line containing copper is formed. The method further includes cutting the fuze line by emitting a laser beam, and applying a composition for etching copper to the substrate to finely etch a cutting area of the fuze line and to substantially remove at least one of a copper residue and a copper oxide residue remaining near the cutting area. The composition for etching copper includes about 0.01 to about 10 percent by weight of an organic acid, about 0.01 to 1.0 percent by weight of an oxidizing agent, and a protic solvent.

Abstract: A method of manufacture of an integrated circuit packaging system includes providing an integrated circuit having an active side and a non-active side; forming a channel through the integrated circuit; forming an indent, having a flange and an indent side, from a peripheral region of the non-active side; and forming a conformal interconnect, having an offset segment, a sloped segment, and a flange segment, under the indent.

Abstract: A method is provided for detecting laser optical paths in integrated circuit (IC) packages. The method provides an IC die encapsulated as a package in a compound of glass spheres and epoxy. Power is supplied to the IC. The IC is scanned with a laser. Typically, a laser wavelength is used that is minimally absorbed by the glass spheres in the epoxy compound of the IC package, and changes in current to the IC are detected. A detected current change is cross-referenced against a scanned IC package surface region. This process identifies an optical pathway underlying the scanned IC package surface region. In some aspects, this process leads to the identification of a glass sphere-collecting package structure underlying the optical pathway. Examples of a glass sphere-collecting structure might include an inner lead wire, lead frame edge, or die edge.

Abstract: A wafer-level chip-scale packaging feature for a semiconductor device is disclosed which has a substrate, a plurality of nail-shaped conducting posts extending from a surface of the substrate, and a plurality of solder balls, where each of the solder balls is connected to one of the nail-shaped conducting posts. When a different-sized solder ball is desired for use, the device can be re-processed by only removing and replacing the cross-members of the nail-shaped conducting posts, which cuts down on the re-processing expense.

Abstract: For electrically connecting a wiring formed on one surface of an insulating substrate such as an FPC to an individual electrode arranged facing the other surface of the substrate, firstly, a through hole and a notch are formed by irradiating a laser beam from above onto the FPC. Next, the FPC is arranged to be positioned such that the individual electrode, the through hole and the notch are overlapped in a plan view. Next, an electroconductive liquid droplet having a diameter greater than a width of the notch is jetted, toward an area formed with the notch, from the one surface side of the FPC. The landed electroconductive liquid droplet flows along the notch in a thickness direction of the substrate due to an action of a capillary force and reaches assuredly to the individual electrode, thereby electrically connecting the wiring and electrode arranged sandwiching the insulating substrate assuredly.

Abstract: A method for manufacturing a thin but robust stack of electrically connected thin film semiconductor elements includes the steps of forming a first element to be stacked: forming a separation layer and a semiconductor element layer over a substrate, forming a wiring connected to the semiconductor element layer, forming a protective material over the semiconductor layer and the wiring, forming a conductive region electrically connected to the wiring in the protective layer, and separating the semiconductor element layer from the substrate along the separation layer. A second element is formed according to the aforementioned process, and the first element is stacked thereon, before separating the second element from its substrate. The first element is bonded to the protective layer of the second element so that the semiconductor element layers of the first and the second element are electrically connected to each other through the protective layer, without damaging the protective layer.

Abstract: A semiconductor substrate is irradiated with accelerated hydrogen ions, thereby forming a damaged region including a large amount of hydrogen. After a single crystal semiconductor substrate and a supporting substrate are bonded to each other, the semiconductor substrate is heated, so that the single crystal semiconductor substrate is separated in the damaged region. A single crystal semiconductor layer which is separated from the single crystal semiconductor substrate is irradiated with a laser beam. The single crystal semiconductor layer is melted by laser beam irradiation, whereby the single crystal semiconductor layer is recrystallized to recover its crystallinity and to planarized a surface of the single crystal semiconductor layer. After the laser beam irradiation, the single crystal semiconductor layer is heated at a temperature at which the single crystal semiconductor layer is not melted, so that the lifetime of the single crystal semiconductor layer is improved.

Abstract: An embedded semiconductor die package is made by mounting a frame carrier to a temporary carrier with an adhesive. The frame carrier includes die mounting sites each having a lead frame interconnect structure around a cavity. A semiconductor die is disposed in each cavity. An encapsulant is deposited in the cavity over the die. A package interconnect structure is formed over the lead frame interconnect structure and encapsulant. The package interconnect structure and lead frame interconnect structure are electrically connected to the die. The frame carrier is singulated into individual embedded die packages. The semiconductor die can be vertically stacked or placed side-by-side within the cavity. The embedded die packages can be stacked and electrically interconnected through the lead frame interconnect structure. A semiconductor device can be mounted to the embedded die package and electrically connected to the die through the lead frame interconnect structure.

Abstract: A method of manufacturing a semiconductor apparatus includes forming an electrode on a semiconductor device, forming a conductive bump on the electrode, placing an external wire on the conductive bump, and laser-welding the external wire and the conductive bump to establish electrical connection.

Abstract: A method for making a semiconductor device with vertical electron injection, including: transferring a monocrystalline thin film onto a first face of a support substrate; producing at least one electronic component from the monocrystalline thin film; forming at least one recess in a second face of the substrate to enable electric or electronic access to the electronic component through the monocrystalline thin film; and producing a vertical electron injector configured to inject electrons into the electronic component.

Abstract: The invention provides a Wafer Level Chip Size Packaging (WLCSP) target and a method for forming it. A WLCSP target is formed by recombining single chips, wafer parts each including two or more chips or half finished packaging targets which have been subjected to at least one previous step of packaging onto a first substrate, or bonding a wafer part which is formed by dicing a whole wafer and includes at least two chips to a second substrate for bonding. Thus, a wafer with a larger size can be packaged through the WLCSP on a WLCSP apparatus with a smaller size while benefiting from the advantages of the WLCSP, the WLCSP apparatus remains applicable within a longer period of time, the cost is lowered, and enterprises may keep up with the development of the market and the increase of the wafer size without having to update the WLCSP apparatus substantially.

Abstract: For electrically connecting a wiring formed on one surface of an insulating substrate such as an FPC to an individual electrode arranged facing the other surface of the substrate, firstly, a through hole and a notch are formed by irradiating a laser beam from above onto the FPC. Next, the FPC is arranged to be positioned such that the individual electrode, the through hole and the notch are overlapped in a plan view. Next, an electroconductive liquid droplet having a diameter greater than a width of the notch is jetted, toward an area formed with the notch, from the one surface side of the FPC. The landed electroconductive liquid droplet flows along the notch in a thickness direction of the substrate due to an action of a capillary force and reaches assuredly to the individual electrode, thereby electrically connecting the wiring and electrode arranged sandwiching the insulating substrate assuredly.

Abstract: A substrate table used for manufacturing a chip is provided. The substrate table includes a substrate stage, a substrate placement surface formed on the substrate stage, and on which a substrate is placed, and a guiding member that can project and retract from the substrate placement surface. The guiding member positions the substrate when the guiding member is at a projected position abutting an edge portion of the substrate placed on the substrate placement surface, and the guiding member retracts at a time of applying a tape to the substrate.

Abstract: A laser processing method including a first step of forming a first groove and a second step of forming a second groove on the workpiece. In the first step, the laser beam is intermittently applied to the first street except the intersections between the first street and the second street, thereby forming a discontinuous groove as the first groove in such a manner that each intersection is not grooved. In the second step, the laser beam is continuously applied to the second street, thereby forming a continuous groove as the second groove intersecting the first groove in such a manner that each intersection is grooved by the second groove. In the second step, heat generated at a portion immediately before each intersection is passed through the intersection to be dissipated forward, thereby suppressing overheating at this portion.

Abstract: A method for manufacturing a thin but robust stack of electrically connected thin film semiconductor elements includes the steps of forming a first element to be stacked: forming a separation layer and a semiconductor element layer over a substrate, forming a wiring connected to the semiconductor element layer, forming a protective material over the semiconductor layer and the wiring, forming a conductive region electrically connected to the wiring in the protective layer, and separating the semiconductor element layer from the substrate along the separation layer. A second element is formed according to the aforementioned process, and the first element is stacked thereon, before separating the second element from its substrate. The first element is bonded to the protective layer of the second element so that the semiconductor element layers of the first and the second element are electrically connected to each other through the protective layer, without damaging the protective layer.

Abstract: A method for breaking an adhesive film mounted on the back of a wafer having a plurality of streets formed in a lattice pattern on the face of the wafer, and having devices formed in a plurality of regions demarcated by the plurality of streets, the devices being divided individually, is adapted to break the adhesive film along the outer peripheral edges of the individual devices, with the adhesive film being stuck to the surface of a dicing tape mounted on an annular frame. The method comprises: a laser processing step of projecting a laser beam with a pulse width of 100 picoseconds or less onto the adhesive film through gaps between the individually divided devices to form deteriorated layers in the adhesive film along the outer peripheral edges of the individual devices; and an adhesive film breaking step of exerting external force on the adhesive film having the deteriorated layers formed therein, to break the adhesive film along the deteriorated layers.

Abstract: A method and jig structure for positioning bare dice is disclosed. The jig structure for positioning at least one bare dice includes a trap having at least one positioning groove wherein the depth of the positioning groove is less than the height of the bare dice. Basing on the positioning groove formed in the tray, once a bare dice is placed in the positioning groove, the partially exposed bare dice can be located directly and precisely vacuum-grabbed by a sucker, so that the number of positioning steps is reduced.

Abstract: The present invention relates to a method for metallizing semiconductor components in which aluminium is used. In particular in the case of products in which the process costs play a big part, such as e.g. solar cells based on silicon, a cost advantage can be achieved with the invention. In addition, the present invention relates to the use of the method, for example in the production of solar cells.

Abstract: A packaging method comprises: forming a circuit board by forming a substantially continuous conductive layer on an insulating board and removing selected portions of the continuous conductive layer to define an electrically conductive trace; laser cutting the electrically conductive trace to define sub-traces electrically isolated from each other by a laser-cut gap formed by the laser cutting; and bonding a light emitting diode (LED) chip to the circuit board across or adjacent to the laser-cut gap, the bonding including operatively electrically connecting an electrode of the LED chip to one of the sub-traces without using an interposed submount. A semiconductor package comprises an LED chip flip-chip bonded to sub-traces of an electrically conductive trace of a circuit board, the sub-traces being electrically isolated from each other by a narrow gap of less than or about 100 microns.

Abstract: A method for fabricating a low cost integrated circuit package (600) includes separating a processed silicon wafer into a plurality of individual die (601) and then positioning the die (603) on a secondary substrate in a face down position for allowing an increased die I/O connection area. The die is covered (605) with one or more epoxy materials to form a group of embedded die packages. One or more pads on the die are then exposed (615) and subsequently connected (617) to an I/O connection in a die I/O connection area. Each of the die are then separated (619) forming singular embedded die packages from the secondary substrate. The method provides a manufacturing process to form a low cost, very high density integrated circuit package using a combination of both wafer scale packaging and wafer level packaging processes.