Abstract: A method of making a circuitized substrate and an electrical assembly utilizing same in which the substrate is comprised of at least two sub-composites in which the dielectric material of at least one of these sub-composites is heated during bonding (e.g., lamination) to the other sufficiently to cause the dielectric material to flow into and substantially fill openings in a conductive layer for the bonded structure. Conductive thru-holes are formed within the bonded structure to couple selected ones of the structure's conductive layers. Formation of an electrical assembly is possible by positioning one or more electrical components (e.g., semiconductor chips or chip carriers) on the final structure and electrically coupling these to the structure's external circuitry.

Abstract: A circuitized substrate including a composite layer comprising a first dielectric sub-layer comprised of a halogen-free resin and fibers dispersed therein and a second dielectric sub-layer without fibers but also including a halogen-free resin with inorganic particulates therein. A method of making such a substrate is also provided, as is a multilayered assembly including one or more such circuitized substrates, possibly in combination with other substrates. An information handling system designed for having one or more such circuitized substrates is also provided.

Abstract: The present invention provides a structure. The structure includes a stack of sheets. Successive sheets in each pair of successive sheets of the stack are coupled to each other by a removable adhesive. The removable adhesive is also disposed on top and bottom surfaces of the stack so as to respectively couple first and second layers to the cop and bottom surfaces of the stack.

Abstract: The glass transmittance of UV light having a wavelength of 365 nanometers is reduced by compounding an oxide or salt of at least one of Fe, Cu, Cr, Ce, Mn and mixtures thereof. The fiberglass cloth can be used for providing reinforced prepregs used in producing printed circuit boards or laminated chip carrier substrates.

Abstract: A method and structure relating to multisegmented plated through holes. A substrate includes a dielectric layer sandwiched between a first laminate layer and a second laminate layer. A through hole is formed through the substrate. The through hole passes through nonplatable dielectric material within the dielectric layer. As a result, subsequent seeding and electroplating of the through hole results in a conductive metal plating forming at a wall of the through hole on a segment of the first laminate layer and on a segment of the second laminate layer, but not on the nonplatable dielectric material of the dielectric layer. Thus, the conductive metal plating is not continuous from the first laminate layer to the second laminate layer.

Abstract: A method for producing small pitch z-axis electrical interconnections in layers of dielectric materials which are applied to printed wiring boards and diverse electronic packages. A method for parallel fabrication of intermediate structures which are subsequently jointed to form a final structure. In addition there is provided a z-interconnected electrical structure, employing dielectric materials such as resin coated copper, employable in the manufacture of diverse type of electronic packages, including printed wiring boards (PWBs), substrates, multi-chip modules and the like.

Abstract: Power and ground planes that are used in Printed Circuit Boards (PCBs) and that comprise porous, conductive materials are disclosed. Using porous power and ground plane materials in PCBs allows liquids (e.g., water and/or other solvents) to pass through the power and ground planes, thus decreasing failures in PCBs (or PCBs used as laminate chip carriers) caused by cathodic/anodic filament growth and delamination of insulators. Porous conductive materials suitable for use in PCBs may be formed by using metal-coated organic cloths (such as polyester or liquid crystal polymers) or fabrics (such as those made from carbon/graphite or glass fibers), using metal wire mesh instead of metal sheets, using sintered metal, or making metal sheets porous by forming an array of holes in the metal sheets. Fabrics and mesh may be woven or random. If an array of holes is formed in a metal sheet, such an array may be formed with no additional processing steps than are performed using conventional PCB assembly methods.

Abstract: A method for fabricating a laminate circuit structure is provided. The method comprises: providing at least two modularized circuitized voltage plane subassemblies wherein each of the subassemblies comprise at least two signal planes having an external and internal surface disposed about an internal voltage plane; providing a dielectric material between the signal and voltage planes; and providing dielectric on each external surface of each signal plane; and providing a non-cured or partially cured curable dielectric composition between the subassemblies wherein the dielectric composition comprises, dielectric material that is of the same material as the dielectric material used in said subassemblies, aligning the subassemblies, and then laminating to cause bonding of the subassemblies.

Abstract: A method of making a multi-layered interconnect structure. First and second electrically conductive members are formed on the first and second dielectric layers, respectively. The dielectric layer are formed on opposing surfaces of a thermally conductive layer. A first and second electrically conductive layer is formed within the first dielectric layer. The second electrically conductive layer includes shielded signal conductors and is positioned between the first electrically conductive layer and the thermally conductive layer. A plated through hole (PTH) formed through the interconnect structure is electrically connected to one of the first and second electrically conductive members and to one of the shielded signal conductors.

Abstract: A substrate and a method of making the substrate is provided. The substrate includes a layer of metal with at least one through hole therein, the layer of metal having an adhesion promoting layer thereon. A layer of a partially cured low-loss polymer or polymer precursor is positioned on the adhesion promoting layer and a plurality of conductive circuit lines are positioned on a portion of the partially cured dielectric layer. The substrate can be used as a building block in the fabrication of a multilayered printed circuit board.

Abstract: A method for producing small pitch z-axis electrical interconnections in layers of dielectric materials which are applied to printed wiring boards and diverse electronic packages. A method for parallel fabrication of intermediate structures which are subsequently jointed to form a final structure. In addition there is provided a z-interconnected electrical structure, employing dielectric materials such as resin coated copper, employable in the manufacture of diverse type of electronic packages, including printed wiring boards (PWBs), substrates, multi-chip modules and the like.

Abstract: A prepreg resin comprising: (a) 98 to 40% by weight based on the total weight of components (a) and (b), of a curable polyphenylene ether resin; (b) 2 to 60% by weight based on the total weight of components (a) and (b), of at least one cyanurate selected from the group consisting of triallyl isocyanurate and triallyl cyanurate; (c) a polymerization initiator comprised of a peroxide functionalized polymer, said peroxide functionalized polymer being fragmented by heat to a plurality of free radical moieties, such as t-butoxide moieties, and a relatively inert moiety having a molecular weight greater than about 1,000. The invention also encompasses a cured resin either as a coating on a substrate, without fiberglass cloth embedded, or a cured prepreg with fiberglass cloth embedded and a method of forming the same.

Abstract: The present invention provides a method of temporarily adhering a stack of sheets together to facilitate drilling a hole through the stack of sheets. The method includes using a temporary adhesive that prevents burring while drilling a hole through the stack.

Abstract: A prepreg resin comprising:

Abstract: Conductive materials that have low coefficients of thermal expansion (CTEs) and that are used for power and ground planes are disclosed. Fibrous materials (such as carbon, graphite, glass, quartz, polyethylene, and liquid crystal polymer fibers) with low CTEs are metallized to provide a resultant conductive material with a low CTE. Such fibers may be metallized in their individual state and then formed into a fabric, or these materials may be formed into a fabric and then metallized or a combination of both metallizations may be used. In addition, a graphite or carbon sheet may be metallized on one or both sides to provide a material that has a low CTE and high conductivity. These metallized, low CTE power and ground planes may be laminated with other planes/cores into a composite, or laminated into a core which is then laminated with other planes/cores into a composite. The resultant composite may be used for printed circuit boards (PCBs) or PCBs used as laminate chip carriers.

Abstract: A method for producing small pitch z-axis electrical interconnections in layers of dielectric materials which are applied to printed wiring boards and diverse electronic packages. A method for parallel fabrication of intermediate structures which are subsequently jointed to form a final structure. In addition there is provided a z-interconnected electrical structure, employing dielectric materials such as resin coated copper, employable in the manufacture of diverse type of electronic packages, including printed wiring boards (PWBs), substrates, multi-chip modules and the like.

Abstract: A method and structure relating to multisegmented plated through holes. A substrate includes a dielectric layer sandwiched between a first laminate layer and a second laminate layer. A through hole is formed through the substrate. The through hole passes through nonplatable dielectric material within the dielectric layer. As a result, subsequent seeding and electroplating of the through hole results in a conductive metal plating forming at a wall of the through hole on a segment of the first laminate layer and on a segment of the second laminate layer, but not on the nonplatable dielectric material of the dielectric layer. Thus, the conductive metal plating is not continuous from the first laminate layer to the second laminate layer.

Abstract: The present invention provides a method of temporarily adhering a stack of sheets together to facilitate drilling a hole through the stack of sheets. The method includes using a temporary adhesive that prevents burring while drilling a hole through the stack.

Abstract: Power and ground planes that are used in Printed Circuit Boards (PCBs) and that comprise porous, conductive materials are disclosed. Using porous power and ground plane materials in PCBs allows liquids (e.g., water and/or other solvents) to pass through the power and ground planes, thus decreasing failures in PCBs (or PCBs used as laminate chip carriers) caused by cathodic/anodic filament growth and delamination of insulators. Porous conductive materials suitable for use in PCBs may be formed by using metal-coated organic cloths (such as polyester or liquid crystal polymers) or fabrics (such as those made from carbon/graphite or glass fibers), using metal wire mesh instead of metal sheets, using sintered metal, or making metal sheets porous by forming an array of holes in the metal sheets. Fabrics and mesh may be woven or random. If an array of holes is formed in a metal sheet, such an array may be formed with no additional processing steps than are performed using conventional PCB assembly methods.

Abstract: Power and ground planes used in Printed Circuit Boards (PCBs) having porous, conductive materials allow liquids (e.g., water and/or other solvents) to pass through the power and ground planes, thus decreasing failures in PCBs (or PCBs used as laminate chip carriers) caused by cathodic/anodic filament growth and delamination of insulators. Porous conductive materials suitable for use in PCBs may be formed by using metal-coated organic cloths (such as polyester or liquid crystal polymers) or fabrics (such as those made from carbon/graphite or glass fibers), using metal wire mesh instead of metal sheets, using sintered metal, or making metal sheets porous by forming an array of holes in the metal sheets. Fabrics and mesh may be woven or random. If an array of holes is formed in a metal sheet, such an array may be formed with no additional processing steps than are performed using conventional PCB assembly methods.