Abstract: A tamper-resistant microchip package contains fluid- or nanofluid-filled capsules, channels, or reservoirs, wherein the fluids, either alone or in combination, can destroy circuitry by etching, sintering, or thermally destructing when reverse engineering of the device is attempted. The fluids are released when the fluid-filled cavities are cut away for detailed inspection of the microchip. Nanofluids may be used for the sintering process, and also to increase the thermal conductivity of the fluid for die thermal management. Through-vias and micro vias may be incorporated into the design to increase circuitry destruction efficacy by improving fluid/chip contact. Thermal interface materials may also be utilized to facilitate chip cooling.

Abstract: A method of making a circuitized substrate in which the substrate includes circuit elements having exposed surfaces defined by two thin layers of permanent photoimaged solder mask material which are applied through fine mesh screens. The use of two thin layers assures effective coverage of the material to precisely expose the desired surfaces in high-density circuit patterns. A circuitized substrate assembly and an information handling system adapted for having one or more such assemblies therein are also provided.

Abstract: A detachable, logic leaf module having dendritic projections on a surface is connected to a recessed area on the surface of a cluster interface board. The projections are used for electrically connecting the logic module device to the cluster interface board or the like, the projections on the surface of the logic leaf being flexibly and conductively wired to the receiving area on the surface of the cluster interface board. The logic leaf connector is removable without the need for solder softening thermal cycles or special tools, and permits the simple removal or replacement of an individual leaf at any time.

Abstract: A method of forming a circuitized substrate for use in electronic packages. A substrate layer is provided that has a copper pad on a surface. A conductive seed layer and a photoresist layer are placed on the surface. The photoresist is developed and conductive material is placed within the developed features and a second conductive material placed on the first conductive material. The photoresist and conductive seed layer are removed to leave a micro-pillar array. The joining and lamination of two circuitized substrate layers utilizes the micro-pillar array for the electrical connection of the circuitized substrate layers.

Abstract: A method of forming a buried resistor within a cavity for use in electronic packages using two glass impregnated dielectric layers, one with a clearance hole, the second with a resistor core, the clearance hole being placed over the resistor core and the assembly fusion bonded. The space remaining around the resistor core is filled with a soldermask material and the assembly is coated with metal. Thru-holes are drilled, cleaned, and plated and then the metal coating is etched and partially removed. The soldermask is then removed and a layer of gold plating is applied to the exposed metal surfaces. The use of glass impregnated dielectric layers and fusion bonding eliminates the fluorinated ethylene propylene resin (FEP) bleed problem associated with previous buried resistor cavity assemblies.

Abstract: A substrate for use in a laminated chip carrier (LCC) and a system in package (SiP) device having a coreless buildup layer and at least one metal and at least one dielectric layer. The coreless buildup dielectric layers can include thermoset and thermoplastic resin.

Abstract: A method of converting a land grid array (LGA) module to a ball grid array (BGA) module by removing and oxidizing portions of the LGA conductive pad features on the upper surface of the LGA module. A BGA solder ball is deposited on the remaining portion of the conductive feature of the LGA module, with subsequent reflowing of the BGA solder ball. By modifying the LGA module to support a BGA structure, excessive heat generated by components placed on the modified LGA pad can be conducted through the BGA structure and into the element on which the LGA module is attached, such as a PCB.

Abstract: A method of forming a circuitized substrate utilizing a conductive nub structure for enhanced interconnection integrity by using a joining core layer with copper outer layer on it, and forming thru-holes in the joining layer. Placing conductive adhesive in the thru-hole prior to removing the copper outer layers from the joining core layer creates an adhesive bump on joining core layer that engages a conductive secondary metal nub placed on the circuitized substrate-to-joining layer contact points, thus creating an enhanced connection between the layers.

Abstract: A circuitized substrate for use in such electrical structures as information handling systems wherein the substrate includes a capacitive substrate as part thereof. The capacitive substrate includes a thin film layer of capacitive material strategically positioned on a conductive layer relative to added electrically conductive elements to in turn provide a plurality of internal capacitors within the final circuitized substrate during operation thereof. A method of making such a circuitized substrate is also provided.

Abstract: An electrically conductive adhesive (ECA) for repairing electrically conductive pad and trace interconnects and a method of repairing interconnect locations. The method of repairing at least one defect within the area of electrically conductive circuitized substrate traces and pads outside of a pristine center area incorporates an ECA and a forming gas plasma. The ECA contains a mixture of components that allow the adhesive to be adapted to specific requirements. Curing the adhesive results in effective electrical connections being formed between the adhesive and the base pad so that the metallurgies of the conductors and of the ECA are effectively combined to engage and repair the conductor defect.

Abstract: Methods of forming embedded, multilayer capacitors in printed circuit boards wherein copper or other electrically conductive channels are formed on a dielectric substrate. The channels may be preformed using etching or deposition techniques. A photoimageable dielectric is an upper surface of the laminate. Exposing and etching the photoimageable dielectric exposes the space between the copper traces. These spaces are then filled with a capacitor material. Finally, copper is either laminated or deposited atop the structure. This upper copper layer is then etched to provide electrical interconnections to the capacitor elements. Traces may be formed to a height to meet a plane defining the upper surface of the dielectric substrate or thin traces may be formed on the remaining dielectric surface and a secondary copper plating process is utilized to raise the height of the traces.

Abstract: A method of making an electronic package designed for interconnecting high density patterns of conductors of an electronic device (e.g., semiconductor chip) and less dense patterns of conductors of hosting circuitized substrates (e.g., chip carriers, PCBs). In one embodiment, the method includes bonding a chip to a single dielectric layer, forming a high density pattern of conductors on one surface of the layer, forming openings in the layer and then depositing metallurgy to form a desired circuit pattern which is then adapted for engaging and being electrically coupled to a corresponding pattern on yet another hosting substrate. According to another embodiment of the invention, an electronic package using a dual layered interposer is provided. Also provided are methods of making circuitized substrate assemblies using the electronic packages made using the invention's teachings.

Abstract: A method of making a circuitized substrate including a resistor comprised of material which includes a polymer resin and a quantity of nano-powders including a mixture of at least one metal component and at least one ceramic component. The ceramic component may be a ferroelectric ceramic and/or a high surface area ceramic and/or a transparent oxide and/or a dope manganite. Alternatively, the material will include the polymer resin and nano-powders, with the nano-powders comprising at least one metal coated ceramic and/or at least one oxide coated metal component. An electrical assembly (substrate and at least one electrical component) and an information handling system (e.g., personal computer) utilizing such a circuitized substrate are also provided.

Abstract: A method of making a circuitized substrate which involves forming a plurality of individual film resistors having approximate resistance values as part of at least one circuit of the substrate, measuring the resistance of a representative (sample) resistor to define its resistance, utilizing these measurements to determine the corresponding precise width of other, remaining film resistors located in a defined proximity relative to the representative resistor such that these remaining film resistors will include a defined resistance value, and then selectively isolating defined portions of the resistive material of these remaining film resistors while simultaneously defining the precise width of the resistive material in order that these film resistors will possess the defined resistance.

Abstract: A circuitized substrate in which two conductive layers (e.g., electroplated copper foil) are bonded (e.g., laminated) to an interim dielectric layer. Each of the two foil surfaces which physically bond to the dielectric are smooth (e.g., preferably by chemical processing) and include a thin, organic layer thereon, while the outer surfaces of both foils are also smooth (e.g., preferably also using a chemical processing step). One of these resulting conductive layers may function as a ground or voltage plane while the other may function as a signal plane with a plurality of individual signal lines as part thereof. An electrical assembly and an information handling system utilizing such a circuitized substrate are also provided.

Abstract: An electronic package with two circuitized substrates which sandwich an interposer therebetween, the interposer electrically interconnecting the substrates while including at least one electrical component (e.g., a power module) substantially therein to provide even further operational capabilities for the resulting package.

Abstract: A multilayered circuitized substrate including a plurality of dielectric layers each comprised of a p-aramid paper impregnated with a halogen-free, low moisture absorptivity resin including an inorganic filler but not including continuous or semi-continuous fiberglass fibers as part thereof, and a first circuitized layer positioned on a first of the dielectric layers. A method of making this substrate is also provided.

Abstract: A substrate for use in a PCB or PWB board having a coreless buildup layer and at least one metal and at least one dielectric layer. The coreless buildup dielectric layers can consist of at least partially cured thermoset resin and thermoplastic resin. The substrate may also contain land grid array (LGA) packaging.

Abstract: A substrate for use in a PCB or PWB board having a coreless buildup layer and at least one metal and at least one dielectric layer. The coreless buildup dielectric layers can consist of at least partially cured thermoset resin and thermoplastic resin.

Abstract: An electronic package with two circuitized substrates which sandwich an interposer therebetween, the interposer electrically interconnecting the substrates and also including an opening therein in which is positioned at least one electrical component, such as a semiconductor chip, coupled to the lower or base substrate. A second component may also be mounted on and electrically coupled to the upper surface of the top or cover circuitized substrate. A method of making such a package is also provided.