Abstract: A thermal controller includes a thermal control interface to receive test data from an automated test equipment (ATE) system and dynamically adjust a target setpoint temperature based on the data and a dynamic thermal controller to receive the target setpoint temperature from the thermal control interface and control a thermal actuator based on the target setpoint temperature.

Abstract: A thermal controller includes a thermal control interface to receive test data from an automated test equipment (ATE) system and dynamically adjust a target setpoint temperature based on the data and a dynamic thermal controller to receive the target setpoint temperature from the thermal control interface and control a thermal actuator based on the target setpoint temperature.

Abstract: An apparatus to test a semiconductive device includes a base plane that holds at least one heat-transfer fluid unit cell. The at least one heat-transfer fluid unit cell includes a fluid supply structure including a supply-orifice cross section as well as a fluid return structure including a return-orifice cross section. The supply-orifice cross section is greater than the return-orifice cross section. A die interface is also included to be a liquid-impermeable material.

Abstract: A method and apparatus to minimize thermal impedance using copper on the die or chip backside. Some embodiments use deposited copper having a thickness chosen to complement a given chip thickness, in order to reduce or minimize wafer warpage. In some embodiments, the wafer, having a plurality of chips (e.g., silicon), is thinned (e.g., by chemical-mechanical polishing) before deposition of the copper layer, to reduce the thermal resistance of the chip. Some embodiments further deposit copper in a pattern of bumps, raised areas, or pads, e.g., in a checkerboard pattern, to thicken and add copper while reducing or minimizing wafer warpage and chip stress.

Abstract: A thermal controller includes a thermal control interface to receive test data from an automated test equipment (ATE) system and dynamically adjust a target setpoint temperature based on the data and a dynamic thermal controller to receive the target setpoint temperature from the thermal control interface and control a thermal actuator based on the target setpoint temperature.

Abstract: An apparatus to test a semiconductive device includes a base plane that holds at least one heat-transfer fluid unit cell. The at least one heat-transfer fluid unit cell includes a fluid supply structure including a supply-orifice cross section as well as a fluid return structure including a return-orifice cross section. The supply-orifice cross section is greater than the return-orifice cross section. A die interface is also included to be a liquid-impermeable material.

Abstract: An apparatus to test a semiconductive device includes a base plane that holds at least one heat-transfer fluid unit cell. The at least one heat-transfer fluid unit cell includes a fluid supply structure including a supply-orifice cross section as well as a fluid return structure including a return-orifice cross section. The supply-orifice cross section is greater than the return-orifice cross section. A die interface is also included to be a liquid-impermeable material.

Abstract: An apparatus to test a semiconductive device includes a base plane that holds at least one heat-transfer fluid unit cell. The at least one heat-transfer fluid unit cell includes a fluid supply structure including a supply-orifice cross section as well as a fluid return structure including a return-orifice cross section. The supply-orifice cross section is greater than the return-orifice cross section. A die interface is also included to be a liquid-impermeable material.

Abstract: Embodiments of an apparatus and method for providing cooling of probes for testing of integrated circuits are generally described herein. In some embodiments, an apparatus comprises a probe head assembly configured to hold one or more probes that are adapted to provide electrical contact with an integrated circuit device under test (DUT), a DUT chuck adapted to hold the DUT for contact with the probes, a seal arranged between the probe head assembly and the DUT chuck to form a chamber when the seal is in contact with the probe head assembly and the DUT chuck, and a first port and a second port arranged to provide fluid flow into and fluid flow out of the chamber.

Abstract: A thermal interface unit includes a pedestal, a first contact surface below the pedestal to interface with a first die and a flat spring to enable the first contact surface to adapt to a variable height of a first die of a multi-chip package (MCP).

Abstract: Embodiments of an apparatus and method for providing cooling of probes for testing of integrated circuits are generally described herein. In some embodiments, an apparatus comprises a probe head assembly configured to hold one or more probes that are adapted to provide electrical contact with an integrated circuit device under test (DUT), a DUT chuck adapted to hold the DUT for contact with the probes, a seal arranged between the probe head assembly and the DUT chuck to form a chamber when the seal is in contact with the probe head assembly and the DUT chuck, and a first port and a second port arranged to provide fluid flow into and fluid flow out of the chamber.

Abstract: A thermal controller includes a thermal control interface to receive test data from an automated test equipment (ATE) system and dynamically adjust a target setpoint temperature based on the data and a dynamic thermal controller to receive the target setpoint temperature from the thermal control interface and control a thermal actuator based on the target setpoint temperature.

Abstract: The formation of electronic assemblies is described. In one embodiment, an electronic assembly includes a semiconductor die and a plurality of spaced apart nanotube structures on the semiconductor die. The electronic assembly also includes a fluid positioned between the spaced apart nanotube structures on the semiconductor die. The electronic assembly also includes a endcap covering the plurality of nanotube structures and the fluid, wherein the endcap is positioned to define a gap between the nanotube structures and an interior surface of the endcap. The endcap is also positioned to form a closed chamber including the working fluid, the nanotube structures, and the gap between the nanotube structures and the interior surface of the endcap.

Abstract: A thermal interface unit includes a pedestal, a first contact surface below the pedestal to interface with a first die and a flat spring to enable the first contact surface to adapt to a variable height of a first die of a multi-chip package (MCP).

Abstract: A structure including a die with at least one via within a semiconductor portion of the die, the via being proximate to a hot spot. The via is at least partially filled with a heat-dissipating material and is also capable of absorbing heat from the hot spot.

Abstract: A carbon nanotube (CNT) array is patterned on a substrate. The substrate can be a microelectronic die or a heat sink for a die. The patterned CNT array is patterned by using a patterned catalyst on the substrate to form the CNT array by growing. The patterned CNT array can also be patterned by using a patterned mask on the substrate to form the CNT array by growing. A computing system that uses the CNT array for heat transfer from the die is also used.

Abstract: A method, apparatus and system with a semiconductor package including a microchimney or thermosiphon using carbon nanotubes to modify the effective thermal conductivity of an integrated circuit die.

Abstract: A method, apparatus and system with a semiconductor package including a microchimney or thermosiphon using carbon nanotubes to modify the effective thermal conductivity of an integrated circuit die.

Abstract: A method and arrangement for dissipating heat from a localized area within a semiconductor die is presented. A semiconductor die is constructed and arranged to have at least one conduit portion therein. At least a portion of the conduit portion is proximate to the localized area. The conduit portion is at least partially filled with a heat-dissipating material. The conduit portion absorbs heat from the localized area and dissipates at least a portion of the heat away from the localized area. As such, thermal stress on the die is reduced, and total heat from the die is more readily dissipated.

Abstract: The formation of electronic assemblies is described. In one embodiment, an electronic assembly includes a semiconductor die and a plurality of spaced apart nanotube structures on the semiconductor die. The electronic assembly also includes a fluid positioned between the spaced apart nanotube structures on the semiconductor die. The electronic assembly also includes a endcap covering the plurality of nanotube structures and the fluid, wherein the endcap is positioned to define a gap between the nanotube structures and an interior surface of the endcap. The endcap is also positioned to form a closed chamber including the working fluid, the nanotube structures, and the gap between the nanotube structures and the interior surface of the endcap.