Abstract: A heat spreader has first and second regions. The second region lies substantially in a plane. At least a portion of the first region of the heat spreader has an out-of-plane dimension greater than an out-of-plane dimension of the second region. The heat spreader is sized and shaped to be placed with the first region of the heat spreader proximate to a first region of a semiconductor die that dissipates more power than a second region of the die during operation.

Abstract: A process for fabricating a low dielectric constant semiconductor comprising the steps of: depositing a first metal layer on a substrate; patterning the first metal layer to produce a patterned first metal wiring; applying a first insulating material onto the patterned first metal wiring to form a support structure; patterning the first insulating material by a contact printing process; depositing a second insulating material of lower dielectric constant onto the support structure; planarizing the second insulating material; depositing a polish-stop film layer over the planarized second insulating material, thereby forming a plurality of metal studs; depositing a second metal layer onto the polish-stop film layer forming interconnects with said studs; and patterning the metal layer to produce a second metal wiring interconnecting to the first wiring via the metal studs.

Abstract: A thermal conductive tape article is provided which is adhered to the surface of an integrated circuit device to dissipate heat from the device. The thermal conductive tape article is preferably corrugated and may have a number of configurations providing an expanded surface area. The corrugated tape article may also have a metal strip bonded to one or both sides of the tape article to form a single-faced or double-faced corrugated tape article. The tape article is preferably made of copper or aluminum.

Abstract: A cooling device having a common cooling distribution unit with multiple compliant cooling elements. Mechanisms are built in to ensure the cooling elements are in good thermal contact with heat generating semiconductor chips of different heights and sizes on a common carrier. The cooling distribution unit has protection structures to prevent the leakage of coolant from the unit. Further reduction of the risk of accidental coolant leakage is provided with the onboard storage of coolant absorbent materials in the coolant distribution unit. The cooling elements have serpentine coolant channels to enhanced the cooling capacity. The compliance of the cooling elements can also be achieved by using concentric tubing to connect the coolant distribution unit to cooling heads on the cooling elements.

Abstract: A cooling device having a common cooling distribution unit with multiple compliant cooling elements. Mechanisms are built in to ensure the cooling elements are in good thermal contact with heat generating semiconductor chips of different heights and sizes on a common carrier. The cooling distribution unit has protection structures to prevent the leakage of coolant from the unit. Further reduction of the risk of accidental coolant leakage is provided with the onboard storage of coolant absorbent materials in the coolant distribution unit. The cooling elements have serpentine coolant channels to enhanced the cooling capacity. The compliance of the cooling elements can also be achieved by using concentric tubing to connect the coolant distribution unit to cooling heads on the cooling elements.

Abstract: Thermal cooling structures of diamond or diamond-like materials are provided for conducting heat away from semiconductor devices. A first silicon-on-insulator embodiment comprises a plurality of thermal paths, formed after shallow trench and device fabrication steps are completed, which extend through the buried oxide and provide heat dissipation through to the underlying bulk silicon substrate. The thermal conduction path material is preferably diamond which has high thermal conductivity with low electrical conductivity. A second diamond trench cooling structure, formed after device fabrication has been completed, comprises diamond shallow trenches disposed between the devices and extending through the buried oxide layer. An alternative diamond thermal cooling structure includes a diamond insulation layer deposited over the semiconductor devices in either an SOI or bulk silicon structure.

Abstract: The present invention provides for globally aligning microelectronic circuit systems, such as communication devices and chips, fabricated on or bonded to the front and back sides of one or more substrates to provide for wireless communications between the circuit systems through the one or more substrates. In one embodiment, two circuit systems situated on opposite sides of a substrate are aligned to provide for wireless communications between the two circuit systems through the substrate. In another embodiment, communication devices situated on one or more substrates are aligned to provide for wireless communications between the communication devices through the one or more substrates. In another embodiment, two chips situated on opposite sides of a transparent substrate are aligned to provide for wireless communications between the two chips through the transparent substrate.

Abstract: A chip packaging system and method for providing enhanced thermal cooling including a first embodiment wherein a diamond thin film is used to replace at least the surface layer of the existing packaging material in order to form a highly heat conductive path to an associated heat sink. An alternative embodiment provides diamond thin film layers disposed on adjacent surfaces of the chip and the chip package. Yet another alternative embodiment includes diamond thin film layers on adjacent chip surfaces in a chip-to-chip packaging structure. A final illustrated embodiment provides for the use of an increased number of solder balls disposed in at least one diamond thin film layer on at least one of a chip and a chip package joined with standard C4 technology.

Abstract: A thermal conductive tape article is provided which is adhered to the surface of an integrated circuit device to dissipate heat from the device. The thermal conductive tape article is preferably corrugated and may have a number of configurations providing an expanded surface area. The corrugated tape article may also have a metal strip bonded to one or both sides of the tape article to form a single-faced or double-faced corrugated tape article. The tape article is preferably made of copper or aluminum.

Abstract: Thermal cooling structures of diamond or diamond-like materials are provided for conducting heat away from semiconductor devices. A first silicon-on-insulator embodiment comprises a plurality of thermal paths, formed after shallow trench and device fabrication steps are completed, which extend through the buried oxide and provide heat dissipation through to the underlying bulk silicon substrate. The thermal conduction path material is preferably diamond which has high thermal conductivity with low electrical conductivity. A second diamond trench cooling structure, formed after device fabrication has been completed, comprises diamond shallow trenches disposed between the devices and extending through the buried oxide layer. An alternative diamond thermal cooling structure includes a diamond insulation layer deposited over the semiconductor devices in either an SOI or bulk silicon structure.

Abstract: The present invention provides for globally aligning microelectronic circuit systems, such as communication devices and chips, fabricated on or bonded to the front and back sides of one or more substrates to provide for wireless communications between the circuit systems through the one or more substrates. In one embodiment, two circuit systems situated on opposite sides of a substrate are aligned to provide for wireless communications between the two circuit systems through the substrate. In another embodiment, communication devices situated on one or more substrates are aligned to provide for wireless communications between the communication devices through the one or more substrates. In another embodiment, two chips situated on opposite sides of a transparent substrate are aligned to provide for wireless communications between the two chips through the transparent substrate.

Abstract: A chip packaging system and method for providing enhanced thermal cooling including a first embodiment wherein a diamond thin film is used to replace at least the surface layer of the existing packaging material in order to form a highly heat conductive path to an associated heat sink. An alternative embodiment provides diamond thin film layers disposed on adjacent surfaces of the chip and the chip package. Yet another alternative embodiment includes diamond thin film layers on adjacent chip surfaces in a chip-to-chip packaging structure. A final illustrated embodiment provides for the use of an increased number of solder balls disposed in at least one diamond thin film layer on at least one of a chip and a chip package joined with standard C4 technology.

Abstract: A two loop heat conversion system for high heat density planar devices in which high density heat in an area adjacent to a surface is transferred into a liquid cooling medium closed loop in a radiated heat to liquid heat transfer component positioned in contact with the surface that is connected, to a liquid to gas medium, heat exchanger in a first loop and a gas medium second loop is arranged to carry away all radiated heat from the assembly and all heat extracted from the liquid in the liquid to gas heat exchanger and exhaust it to the ambient. The radiated heat transfer component of the invention provides a transition in manufacturing that is practiced employing the planar type tools in fabrication which usually can neither be practiced manually or observed without substantial magnification.

Abstract: A chip packaging system and method for providing enhanced thermal cooling including a first embodiment wherein a diamond thin film is used to replace at least the surface layer of the existing packaging material in order to form a highly heat conductive path to an associated heat sink. An alternative embodiment provides diamond thin film layers disposed on adjacent surfaces of the chip and the chip package. Yet another alternative embodiment includes diamond thin film layers on adjacent chip surfaces in a chip-to-chip packaging structure. A final illustrated embodiment provides for the use of an increased number of solder balls disposed in at least one diamond thin film layer on at least one of a chip and a chip package joined with standard C4 technology.

Abstract: A wafer structure and a method of making the same, upon which semiconductor devices may be formed, comprises first and second wafers. The first wafer comprises a first substrate having a thin oxide layer formed on a bottom surface thereof, the first substrate having a characteristic thermal expansion coefficient. The second wafer comprises a second substrate having an insulation layer formed on a top surface thereof, the insulation layer having a characteristic thermal expansion coefficient substantially matched with the characteristic thermal expansion coefficient of the first substrate and further having a high thermal conductivity. The second wafer further comprises a thin oxide layer formed on a top surface of the insulation layer, wherein the first thin oxide layer of the first wafer is bonded to the second thin oxide layer of the second wafer.

Abstract: A wafer structure and a method of making the same, upon which semiconductor devices may be formed, comprises first and second wafers. The first wafer comprises a first substrate having a thin oxide layer formed on a bottom surface thereof, the first substrate having a characteristic thermal expansion coefficient. The second wafer comprises a second substrate having an insulation layer formed on a top surface thereof, the insulation layer having a characteristic thermal expansion coefficient substantially matched with the characteristic thermal expansion coefficient of the first substrate and further having a high thermal conductivity. The second wafer further comprises a thin oxide layer formed on a top surface of the insulation layer, wherein the first thin oxide layer of the first wafer is bonded to the second thin oxide layer of the second wafer.