Abstract: An integrated circuit device incorporating a metallurgical bond to enhance thermal conduction to a heat sink. In a semiconductor device, a surface of an integrated circuit die is metallurgically bonded to a surface of a heat sink. In an exemplary method of manufacturing the device, the upper surface of a package substrate includes an inner region and a peripheral region. The integrated circuit die is positioned over the substrate surface and a first surface of the integrated circuit die is placed in contact with the package substrate. A metallic layer is formed on a second opposing surface of the integrated circuit die. A preform is positioned on the metallic layer and a heat sink is positioned over the preform. A joint layer is formed with the preform, metallurgically bonding the heat sink to the second surface of the integrated circuit die.

Abstract: Disclosed herein are novel damage detection circuitries implemented on the periphery of a semiconductor device. The circuitries disclosed herein enable the easy identification of cracks and deformation, and other types of damage that commonly occur during test and assembly processes of semiconductor devices.

Abstract: An integrated circuit device incorporating a metallurgical bond to enhance thermal conduction to a heat sink. In a semiconductor device, a surface of an integrated circuit die is metallurgically bonded to a surface of a heat sink. In an exemplary method of manufacturing the device, the upper surface of a package substrate includes an inner region and a peripheral region. The integrated circuit die is positioned over the substrate surface and a first surface of the integrated circuit die is placed in contact with the package substrate. A metallic layer is formed on a second opposing surface of the integrated circuit die. A preform is positioned on the metallic layer and a heat sink is positioned over the preform. A joint layer is formed with the preform, metallurgically bonding the heat sink to the second surface of the integrated circuit die.

Abstract: The present invention provides a solder bump structure. In one aspect, the solder bump structure is utilized in a semiconductor device, such as an integrated circuit. The semiconductor device comprises active devices located over a semiconductor substrate, interconnect layers comprising copper formed over the active devices, and an outermost metallization layer positioned over the interconnect layers. The outermost metallization layer comprises aluminum and includes at least one bond pad and at least one interconnect runner each electrically connected to an interconnect layer. An under bump metallization layer (UBM) is located over the bond pad, and a solder bump is located over the UBM.

Abstract: Disclosed herein are novel support structures for pad reinforcement in conjunction with new bond pad designs for semiconductor devices. The new bond pad designs avoid the problems associated with probe testing by providing a probe region that is separate from a wire bond region. Separating the probe region 212 from the wire bond region 210 and forming the bond pad 211 over active circuitry has several advantages. By separating the probe region 212 from the wire bond region 210, the wire bond region 210 is not damaged by probe testing, allowing for more reliable wire bonds. Also, forming the bond pad 211 over active circuitry, including metal interconnect layers, allows the integrated circuit to be smaller.

Abstract: Disclosed herein are novel support structures for pad reinforcement in conjunction with new bond pad designs for semiconductor devices. The new bond pad designs avoid the problems associated with probe testing by providing a probe region that is separate from a wire bond region. Separating the probe region 212 from the wire bond region 210 and forming the bond pad 211 over active circuitry has several advantages. By separating the probe region 212 from the wire bond region 210, the wire bond region 210 is not damaged by probe testing, allowing for more reliable wire bonds. Also, forming the bond pad 211 over active circuitry, including metal interconnect layers, allows the integrated circuit to be smaller.