Abstract: An optical package includes a laser die a photonics die. The laser die generates light and includes a laser facet that emits light. The photonics die modulates light emitted from the facet and includes an internal waveguide optically connected with the facet and one or more standoff contacts, flush contacts, or reduced contacts. The optical package may also include an external waveguide optically connected to the photonics die. The external waveguide may be optically connected to the photonics die prior to electrically connecting the photonics die with an interposer. The standoff contacts extend from a device side of the photonics die beyond the laser die, the flush contacts extend from the device side of the photonics die to be coplanar with the laser die, and the reduced contacts extend from the device side of the photonics short of the laser die.

Abstract: A tamper resistant, integrated circuit (IC) module includes a ceramic-based chip carrier, one or more integrated circuit chips attached to the chip carrier, and a cap structure attached to the chip carrier, covering the one or more integrated circuit chips. A conductive grid structure is formed in the chip carrier and cap structure, the conductive structure having a plurality of meandering lines disposed in an x-direction, a y-direction, and a z-direction. The conductive grid structure is configured so as to detect an attempt to penetrate the IC module.

Abstract: A method and device comprising an easily reworkable alpha particle barrier is provided. The easily reworkable alpha particle barrier is applied in the space between the surface of the chip and the surface of the substrate, and reduces soft error rate (SER). Further, the easily reworkable alpha particle barrier material is chosen from the group of an organic material, a hydrocarbon, more specifically a polyalphaolefin (PAO) oil, and a polymer or filled polymer; wherein the polyalphaolefin oil has a viscosity below 1000 cSt (at 100° C.). The easily reworkable alpha particle barrier material can be used with multichip modules (MCM's) allowing easy device rework of one or more dies without affecting other dies on the same substrate.

Abstract: A stacked semiconductor apparatus has at least one die attached to a first side of a carrier substrate. A first circuitized substrate is attached to the first side of the carrier substrate and overlying the at least one die in a manner such that the first circuitized substrate serves as an electrical interconnection device and a heat spreading lid. The first circuitized substrate is further configured so as to facilitate cooling of the at least one die by at least a cross flow of a cooling medium therethrough.

Abstract: A chip package including a chip extension for containing thermal interface material (TIM) and improves chip cooling, and a related method, are disclosed. In particular, the chip package includes a chip, a cooling structure coupled to the chip via a TIM, and a chip extension may be thermally coupled to an outer edge of the chip. A TIM placed between the chip and the cooling structure is contained during thermal cycling by the chip extension such that void formation at the edge of the chip, which can move between the chip and cooling structure, is suppressed. The chip extension also improves lateral heat dissipation by providing a greater thermal contact area between the cooling structure and the chip and, if needed, the substrate at a much lower cost than using larger die with lower production unit output from a wafer.

Abstract: A stacked semiconductor apparatus has at least one die attached to a first side of a carrier substrate. A first circuitized substrate is attached to the first side of the carrier substrate and overlying the at least one die in a manner such that the first circuitized substrate serves as an electrical interconnection device and a heat spreading lid. The first circuitized substrate is further configured so as to facilitate cooling of the at least one die by at least a cross flow of a cooling medium therethrough.

Abstract: A tamper resistant, integrated circuit (IC) module includes a ceramic-based chip carrier, one or more integrated circuit chips attached to the chip carrier, and a cap structure attached to the chip carrier, covering the one or more integrated circuit chips. A conductive grid structure is formed in the chip carrier and cap structure, the conductive structure having a plurality of meandering lines disposed in an x-direction, a y-direction, and a z-direction. The conductive grid structure is configured so as to detect an attempt to penetrate the IC module.

Abstract: An integrated circuit chip mounting structure includes a chip carrier electrically connected to a circuit board with an integrated circuit chip mounted on the chip carrier. In addition, a thermally conductive device is thermally connected to the chip and a set of compressible support members are provided to transmit a portion of an applied compressive load from the thermally conductive device to the chip and chip carrier.

Abstract: An integrated circuit structure and a method of manufacturing, wherein the method comprises forming a first via in an interconnect layer of the substrate, wherein the first via comprises a first size diameter; and forming a second via in the interconnect layer, wherein the second via comprises a second size diameter, the second size diameter being dimensioned larger than the first size diameter, wherein the second via comprises a non-uniform circumference, and wherein the substrate is configured in an approximately 1:1 ratio (i.e., approximately equal number) of the first and second vias. The first and second vias are laser formed or are formed by any of mechanical punching and photolithography. The second via is formed by sequentially forming multiple partially overlapping vias dimensioned and configured with the first size diameter. The first and second vias are arranged in a grid to allow for wiring of electronic devices.

Abstract: The present invention provides a method for producing a temporary chip carrier for semiconductor chip burn-in test and speed sorting. A multi-layered substrate or card, usually comprised of one of various materials is made by offsetting the conductor-filled vias or holes in the outer few layers with the outer most layer not being filled with a conductor, such that a partially filled via or hole is produced. This effectively produces a smaller surface conductor feature, on which the semiconductor chip is temporarily attached, electrically tested, and subsequently removed using various methods, at forces much lower than normal chip removal processes require.