Abstract: A method and structure are provided for implementing a dual optical and electrical land grid array (LGA) contact. A contact for electrical and optical connection between a module and a printed circuit board (PCB) includes material providing electrical connection and an integrated material providing an optical connection; and the contact is used in a land grid array (LGA) arrangement.

Abstract: A method for aligning a chip onto a substrate is disclosed. The method includes, depositing a ferrofluid, onto a substrate that has one or more pads that electrically couple to a semiconductor layer. The method can include a chip with solder balls electrically coupled to the logic elements of the chip, which can be placed onto the deposited ferrofluid, where the chip is supported on the ferrofluid, in a substantially coplanar orientation to the substrate. The method can include determining if the chip is misaligned from a desired location on the substrate. The method can include adjusting the current location of the chip in response to determining that the solder balls of the chip are misaligned from the desired location on the pads of the substrate, until the chip is aligned in the desired location.

Abstract: A method for aligning a chip onto a substrate is disclosed. The method includes, depositing a ferrofluid, onto a substrate that has one or more pads that electrically couple to a semiconductor layer. The method can include a chip with solder balls electrically coupled to the logic elements of the chip, which can be placed onto the deposited ferrofluid, where the chip is supported on the ferrofluid, in a substantially coplanar orientation to the substrate. The method can include determining if the chip is misaligned from a desired location on the substrate. The method can include adjusting the current location of the chip in response to determining that the solder balls of the chip are misaligned from the desired location on the pads of the substrate, until the chip is aligned in the desired location.

Abstract: A cooling apparatus for dissipating heat from an electronic module is disclosed. The cooling apparatus may include a thermally conductive shell having a surface in contact with, and configured to conduct heat away from, the module. The apparatus may also include an electrically insulative layer positioned between, and configured to conduct heat from, the module to the shell. The apparatus may also include an electrical cord, attached to the module that contains a thermally conductive layer in thermally conductive contact with the shell that is configured to conduct heat away from the shell. The apparatus may also include an electrically insulative layer between the thermally conductive layer and an electrical conductor within the electrical cord. The apparatus may also include an electrically insulative layer, positioned between the thermally conductive layer and an electrical cord outer surface, configured to convectively dissipate heat from the thermally conductive layer.

Abstract: A cooling apparatus for dissipating heat from an electronic module is disclosed. The cooling apparatus may include a thermally conductive shell having a surface in contact with, and configured to conduct heat away from, the module. The apparatus may also include an electrically insulative layer positioned between, and configured to conduct heat from, the module to the shell. The apparatus may also include an electrical cord, attached to the module that contains a thermally conductive layer in thermally conductive contact with the shell that is configured to conduct heat away from the shell. The apparatus may also include an electrically insulative layer between the thermally conductive layer and an electrical conductor within the electrical cord. The apparatus may also include an electrically insulative layer, positioned between the thermally conductive layer and an electrical cord outer surface, configured to convectively dissipate heat from the thermally conductive layer.

Abstract: An apparatus for cooling a heat-producing electronic device is disclosed. The apparatus may include a thermally conductive vessel to mate with and contain a working fluid in contact with the heat-producing electronic device. A bottom side of the thermally conductive vessel may include a sealing surface defining an aperture and configured to mate with, and inside a perimeter of, a top surface of the heat-producing electronic device. The thermally conductive vessel may also include an evaporative cavity formed by mating the thermally conductive vessel with the heat-producing electronic device, and having a wall that is the top surface of the heat-producing electronic device and a wall that is an interior surface of the thermally conductive vessel. The thermally conductive vessel may also include a condensing cavity adjoining the evaporative cavity, to receive heat by condensing the working fluid from a vapor state to a liquid state.

Abstract: A method and structures are provided for implementing individual integrated circuit chip attach in a three dimensional (3D) stack. A plurality of hollow copper pillars is formed, and the hollow copper pillars are coated with lead free solder using vapor deposition.

Abstract: A method and structures are provided for implementing individual integrated circuit chip attach in a three dimensional (3D) stack. A plurality of hollow copper pillars is formed, and the hollow copper pillars are coated with lead free solder using vapor deposition.