Abstract: The present disclosure relates generally to microelectronic technology, and more specifically, to an apparatus used for the cooling of active electronic devices utilizing micro-channels or micro-trenches, and a technique for fabricating the same.

Abstract: Trenches may be formed in the upper surfaces of a pair of wafers. Each trench may be coated with a catalyst that is capable of removing oxygen or hydrogen from a fluid used for cooling in a system making use of the electroosmotic effect for pumping. Channels may be formed to communicate fluid to and from the trench coated with the catalyst. The substrates may be combined in face-to-face abutment, for example using copper-to-copper bonding to form a re-combiner.

Abstract: A stack of heat generating integrated circuit chips may be provided with intervening cooling integrated circuit chips. The cooling integrated circuit chips may include microchannels for the flow of the cooling fluid. The cooling fluid may be pumped using the integrated electroosmotic pumps. Removal of cooling fluid gases may be accomplished using integrated re-combiners in some embodiments.

Abstract: An electroosmotic pump may be fabricated using semiconductor processing techniques with a nanoporous open cell dielectric frit. Such a frit may result in an electroosmotic pump with better pumping capabilities.

Abstract: A method of forming a silicon (Si) via in vertically stacked wafers is provided with a contact plug extending from selected metallic lines of a top wafer and an etch stop layer formed prior to the contact plug. Such a method comprises selectively etching through the silicon (Si) of the top wafer until stopped by the etch stop layer to form the Si via; depositing an oxide layer to insulate a sidewall of the Si via; forming a barrier layer on the oxide layer and on the bottom of the Si via; and depositing a conduction metal into the Si via to provide electrical connection between active IC devices located on vertically stacked wafers and an external interconnect.

Abstract: An integrated circuit to be cooled may be abutted in face-to-face abutment with a cooling integrated circuit. The cooling integrated circuit may include electroosmotic pumps to pump cooling fluid through the cooling integrated circuits via microchannels to thereby cool the heat generating integrated circuit. The electroosmotic pumps may be fluidically coupled to external radiators which extend upwardly away from a package including the integrated circuits. In particular, the external radiators may be mounted on tubes which extend the radiators away from the package.

Abstract: A die package and a method and apparatus for integrating an electro-osmotic pump and a microchannel cooling assembly into a die package.

Abstract: A microelectronic assembly is provided, having thermoelectric elements formed on a die so as to pump heat away from the die when current flows through the thermoelectric elements. In one embodiment, the thermoelectric elements are integrated between conductive interconnection elements on an active side of the die. In another embodiment, the thermoelectric elements are on a backside of the die and electrically connected to a carrier substrate on a front side of the die. In a further embodiment, the thermoelectric elements are formed on a secondary substrate and transferred to the die.

Abstract: A die package and a method and apparatus for integrating an electro-osmotic pump and a microchannel cooling assembly into a die package.

Abstract: Method and structure for optimizing and controlling diffusional creep at metal contact interfaces are disclosed. Embodiments of the invention accommodate height variations in adjacent contacts, decrease planarization uniformity requirements, and facilitate contact bonding at lower temperatures and pressures by employing shapes and materials that respond predictably to compressive interfacing loads.

Abstract: A method of making a semiconductor device is described. That method comprises forming a conductive layer that contacts a via, such that the conductive layer includes a higher concentration of an electromigration retarding amount of a dopant near the via than away from the via.

Abstract: An integrated electroosmotic pump may be incorporated in the same integrated circuit package with a re-combiner, and an integrated circuit chip to be cooled by fluid pumped by the electroosmotic pump.

Abstract: The present disclosure relates generally to microelectronic technology, and more specifically, to an apparatus used for the cooling of active electronic devices utilizing micro-channels or micro-trenches, and a technique for fabricating the same.

Abstract: A method of vertically stacking wafers is provided to form three-dimensional (3D) wafer stack. Such method comprising: selectively depositing a plurality of metallic lines on opposing surfaces of adjacent wafers; bonding the adjacent wafers, via the metallic lines, to establish electrical connections between active devices on vertically stacked wafers; and forming one or more vias to establish electrical connections between the active devices on the vertically stacked wafers and an external interconnect. Metal bonding areas on opposing surfaces of the adjacent wafers can be increased by using one or more dummy vias, tapered vias, or incorporating an existing copper (Cu) dual damascene process.

Abstract: A method of forming a silicon (Si) via in vertically stacked wafers is provided with a contact plug extending from selected metallic lines of a top wafer and an etch stop layer formed prior to the contact plug. Such a method comprises selectively etching through the silicon (Si) of the top wafer until stopped by the etch stop layer to form the Si via; depositing an oxide layer to insulate a sidewall of the Si via; forming a barrier layer on the oxide layer and on the bottom of the Si via; and depositing a conduction metal into the Si via to provide electrical connection between active IC devices located on vertically stacked wafers and an external interconnect.

Abstract: According to one embodiment a method is disclosed. The method includes applying a photoresist layer to a first wafer, etching the first wafer, bonding the first wafer to a second wafer and thinning the first wafer; wherein an unsupported bevel portion of the first wafer is removed.

Abstract: A closed-loop based timing signal distribution architecture includes at least one signal source coupled to a signal path disposed in a closed loop arrangement to facilitate generation of a standing wave signal within the signal path. In one embodiment, at least one receiver is coupled to the signal path to generate at least one digital clock signal based upon the standing wave signal.

Abstract: A device where the electrodes of an electroosmotic pump are located directly in the flow-producing region of the electroosmotic pump is described as well as methods of forming such a device. Placing the electrodes of an electroosmotic pump directly in the flow-producing region of the electroosmotic pump may increase the flow rate of a cooling fluid that is pumped through the pump. The cooling fluid may then remove a greater amount of heat from the substrate over which it is flowed. The substrate may be the non-device side of a die or a thermal management chip that is placed in direct contact with the non-device side of a die. In these instances the electroosmotic pump may be part of a microelectronic package containing the die or the thermal management chip.

Abstract: A stack of heat generating integrated circuit chips may be provided with intervening cooling integrated circuit chips. The cooling integrated circuit chips may include microchannels for the flow of the cooling fluid. The cooling fluid may be pumped using the integrated electroosmotic pumps. Removal of cooling fluid gases may be accomplished using integrated re-combiners in some embodiments.

Abstract: Various methods of forming backside connections on a wafer stack are disclosed. To form the backside connections, vias are formed in a first wafer that is to be bonded with a second wafer. The vias used for the backside connections are formed on a side of the first wafer along with an interconnect structure, and the backside connections are formed on an opposing side of the first wafer using these vias.