Abstract: A method and structure to electrically couple a semiconductor device to a substrate that is divided into a plurality of segments. Alternatively, a semiconductor device may be divided into a plurality of segments and the plurality of segments are electrically coupled to a single substrate.

Abstract: A method and structure to electrically couple a semiconductor device to a substrate that is divided into a plurality of segments. Alternatively, a semiconductor device may be divided into a plurality of segments and the plurality of segments are electrically coupled to a single substrate.

Abstract: A method and structure to electrically couple a semiconductor device to a substrate that is divided into a plurality of segments. Alternatively, a semiconductor device may be divided into a plurality of segments and the plurality of segments are electrically coupled to a single substrate.

Abstract: A method and structure to electrically and mechanically join a first a first electrically conductive pad on a first substrate to a second electrically conductive pad on a second substrate using a solder joint that includes a low-melt solder alloy composition. The second electrically conductive pad has a geometry that compels a gap size of a gap between the first substrate and the second substrate to exceed a distance between the first substrate and a surface of the second pad.

Abstract: A chip carrier structure and method for forming the same having a receptor pad formed therein. The structure comprises a circuitized substrate having a conductive element on the surface, an External Dielectric Layer mounted on the circuitized substrate with an opening positioned above the conductive element to form a microvia. The walls of the microvia are first treated to enhance copper adhesion and then are electroplated to provide a receptor pad. Finally, a solder paste is deposited within the microvia to create a solder deposit or bump.

Abstract: An encapsulated semiconductor chip module. The chip module has the overlying encapsulant adhered directly and integrally to bare portions of the substrate to which the chip is mounted. This configuration enhances the adhesion and inhibits unintended delamination of the encapsulant from the balance of the module. The module is made by patterning anchor openings into the solder mask. The anchor openings expose corresponding portions of the substrate. It is important to locate the anchor openings over parts of the substrate that do not have circuitry on them, that is, on bare portions, so as to avoid corrosion or contamination of the circuit connections.

Abstract: A method and structure for reducing chip carrier flexing during thermal cycling. A semiconductor chip is coupled to a stiff chip carrier (i.e., a chip carrier having an elastic modulus of at least about 3×105 psi), and there is no stiffener ring on a periphery of the chip carrier. Without the stiffener ring, the chip carrier is able to undergo natural flexing (in contrast with constrained flexing) in response to a temperature change that induces thermal strains due to a mismatch in coefficient of thermal expansion between the chip and the chip carrier. If the temperature at the chip carrier changes from room temperature to a temperature of about −40° C., a maximum thermally induced displacement of a surface of the chip carrier is at least about 25% less if the stiffener ring is absent than if the stiffener ring is present.

Abstract: Mixtures for attaching a semiconductor chip to a substrate. The semiconductor chip has an array of joining material bumps, such as C4 solder balls. The substrate has an array of conductive pads corresponding to the array of joining material bumps. In a first embodiment the fixture has a body having a first cavity containing the semiconductor chip and a second cavity for containing the substrate. The substrate is placed over the semiconductor chip with the conductive pads opposing and in contact with the joining material bumps, such that during reflow of the joining material bumps, the weight of the substrate acts against the joining material bumps and aids in the attachment of the semiconductor chip to the substrate to form electrical connections therebetween.

Abstract: A method and structure for reducing chip carrier flexing during thermal cycling. A semiconductor chip is coupled to a stiff chip carrier (i.e., a chip carrier having an elastic modulus of at least about 3×105 psi), and there is no stiffener ring on a periphery of the chip carrier. Without the stiffener ring, the chip carrier is able to undergo natural flexing (in contrast with constrained flexing) in response to a temperature change that induces thermal strains due to a mismatch in coefficient of thermal expansion between the chip and the chip carrier. If the temperature at the chip carrier changes from room temperature to a temperature of about −40° C., a maximum thermally induced displacement of a surface of the chip carrier is at least about 25% less if the stiffener ring is absent than if the stiffener ring is present.

Abstract: An electronic package and method of making the electronic package is provided. A layer of dielectric material is positioned on a first surface of a substrate which includes a plurality of conductive contacts. At least one through hole is formed in the layer of dielectric material in alignment with at least one of the plurality of conductive contacts. A conductive material is positioned in the at least one through hole substantially filling the through hole. At least one conductive member is positioned on the conductive material in the through hole and in electrical contact with the conductive material. The electronic package improves field operating life of an assembly which includes a semiconductor chip attached to a second surface of the substrate and a printed wiring board attached to the conductive members.

Abstract: A surface metal balancing structure for a chip carrier, and an associated method of fabrication, to reduce or eliminate thermally induced chip carrier flexing. A substrate, such as a chip carrier made of organic dielectric material, is formed and includes: internal circuitization layers, a plated through hole, and outer layers comprised of an allylated polyphenylene ether. A stiffener ring for mechanically stabilizing the substrate is bonded to an outer portion, such as an outer perimeter portion, of the top surface of the substrate, in light of the soft and conformal organic material of the substrate. The top and bottom surfaces of the substrate have metal structures, such as copper pads and copper circuitization, wherein a surface area (A) multiplied by a coefficient of thermal expansion (C) is greater for the metal structure at the bottom surface than for the metal structure at the top surface.

Abstract: A chip carrier structure and method for forming the same having a receptor pad formed therein. The structure comprises a circuitized substrate having a conductive element on the surface, an External Dielectric Layer mounted on the circuitized substrate with an opening positioned above the conductive element to form a microvia. The walls of the microvia are first treated to enhance copper adhesion and then are electroplated to provide a receptor pad. Finally, a solder paste is deposited within the microvia to create a solder deposit or bump.

Abstract: An electronic package and method of making the electronic package is provided. A layer of dielectric material is positioned on a first surface of a substrate which includes a plurality of conductive contacts. At least one through hole is formed in the layer of dielectric material in alignment with at least one of the plurality of conductive contacts. A conductive material is positioned in the at least one through hole substantially filling the through hole. At least one conductive member is positioned on the conductive material in the through hole and in electrical contact with the conductive material. The electronic package improves field operating life of an assembly which includes a semiconductor chip attached to a second surface of the substrate and a printed wiring board attached to the conductive members.

Abstract: A chip mounting assembly is provided which includes a dielectric substrate having at least one integrated circuit (I/C) chip mounted thereon. An electrically conductive cover plate is in contact with all the chips with an electrically non-conducting thermally conducting adhesive. A stiffener member is provided which is mounted on the substrate and laterally spaced from the integrated circuit chip. At least one electrically conductive ground pad is formed on the substrate. The stiffener has at least one through opening therein and electrically conductive adhesive extending through each opening and contacting the cover plate and each ground pad. The invention also provides a method of forming such an I/C chip assembly.

Abstract: Fixtures for attaching a semiconductor chip to a substrate. The semiconductor chip has an array of joining material bumps, such as C4 solder balls. The substrate has an array of conductive pads corresponding to the array of joining material bumps. In a first embodiment the fixture has a body having a first cavity for containing the semiconductor chip and a second cavity in communication with the first cavity for containing the substrate. Whereby the substrate is placed over the semiconductor chip with the conductive pads opposing and in contact with the joining material bumps, such that during reflow of the joining material bumps, the weight of the substrate acts against the joining material bumps and aids in the attachment of the semiconductor chip to the substrate to form electrical connections therebetween.

Abstract: An electronic package and method of making the electronic package is provided. A layer of dielectric material is positioned on a first surface of a substrate which includes a plurality of conductive contacts. At least one through hole is formed in the layer of dielectric material in alignment with at least one of the plurality of conductive contacts. A conductive material is positioned in the at least one through hole substantially filling the through hole. At least one conductive member is positioned on the conductive material in the through hole and in electrical contact with the conductive material. The electronic package improves field operating life of an assembly which includes a semiconductor chip attached to a second surface of the substrate and a printed wiring board attached to the conductive members.

Abstract: A chip mounting assembly includes a dielectric substrate having at least one integrated circuit (I/C) chip mounted thereon. An electrically conductive cover plate is in contact with all the chips with an electrically non-conducting thermally conducting adhesive. A stiffener member is provided which is mounted on the substrate and laterally spaced from the integrated circuit chip. At least one electrically conductive ground pad is formed on the substrate. The stiffener has at least one through opening therein and electrically conductive adhesive extending through each opening and contacting the cover plate and each ground pad.

Abstract: A chip mounting assembly is provided which includes a dielectric substrate having at least one integrated circuit (I/C) chip mounted thereon. An electrically conductive cover plate is in contact with all the chips with an electrically non-conducting thermally conducting adhesive. A stiffener member is provided which is mounted on the substrate and laterally spaced from the integrated circuit chip. At least one electrically conductive ground pad is formed on the substrate. The stiffener has at least one through opening therein and electrically conductive adhesive extending through each opening and contacting the cover plate and each ground pad. The invention also provides a method of forming such an I/C chip assembly.

Abstract: Fixtures for attaching a semiconductor chip to a substrate. The semiconductor chip has an array of joining material bumps, such as C4 solder balls. The substrate has an array of conductive pads corresponding to the array of joining material bumps. In a first embodiment the fixture has a body having a first cavity for containing the semiconductor chip and a second cavity in communication with the first cavity for containing the substrate. Whereby the substrate is placed over the semiconductor chip with the conductive pads opposing and in contact with the joining material bumps, such that during reflow of the joining material bumps, the weight of the substrate acts against the joining material bumps and aids in the attachment of the semiconductor chip to the substrate to form electrical connections therebetween.

Abstract: An encapsulated semiconductor chip module. The chip module has the overlying encapsulant adhered directly and integrally to bare portions of the substrate to which the chip is mounted. This configuration enhances the adhesion and inhibits unintended delamination of the encapsulant from the balance of the module. The module is made by patterning anchor openings into the solder mask. The anchor openings expose corresponding portions of the substrate. It is important to locate the anchor openings over parts of the substrate that do not have circuitry on them, that is, on bare portions, so as to avoid corrosion or contamination of the circuit connections.