Abstract: Processes for adjusting dimensions of dielectric bond line materials in stacks of microelectronic components, and related material films, articles and assemblies.

Abstract: A non-elastic material layer is formed above a carrier wafer. An oxide layer is formed above the non-elastic material layer. Multiple integrated circuit die are bonded on the oxide layer using an oxide to oxide bond to form a reconstructed wafer.

Abstract: Disclosed are methods and apparatus for protecting dielectric films on microelectronic components from contamination associated with singulation, picking and handling of singulated microelectronic components from a wafer for assembly with other components.

Abstract: A semiconductor manufacturing system comprises a laser and a heated bond tip and is configured to bond a die stack in a semiconductor assembly. The semiconductor assembly includes a wafer, manufacture from a material that is optically transparent to a beam emitted by the laser and configured to support a die stack comprising a plurality of semiconductor dies. A metal film is deposited on the wafer and heatable by the beam emitted by the laser. The heated bond tip applies heat and pressure to the die stack, compressing the die stack between the heated bond tip and the metal film and thermally bonding dies in the stack by heat emitted by the heated bond tip and the metal film when the metal film is heated by the beam emitted from the laser.

Abstract: A semiconductor device assembly can include a first die package comprising a bottom side; a top side; and lateral sides extending between the top and bottom sides. The assembly can include an encapsulant material encapsulating the first die package. In some embodiments, the assembly includes a cooling cavity in the encapsulant material. The cooling cavity can have a first opening; a second opening; and an elongate channel extending from the first opening to the second opening. In some embodiments, the elongate channel surrounds at least two of the lateral sides of the first die package. In some embodiments, the elongate channel is configured to accommodate a cooling fluid.

Abstract: A semiconductor device assembly having a semiconductor device attached to a substrate with a foil layer on a surface of the substrate. A layer of adhesive connects the substrate to a first surface of the semiconductor device. The semiconductor device assembly enables processing on the second surface of the semiconductor device. An energy pulse may be applied to the foil layer causing an exothermic reaction to the foil layer that releases the substrate from the semiconductor device. The semiconductor device assembly may include a release layer positioned between the foil layer and the layer of adhesive that connects the substrate to the semiconductor device. The heat generated by the exothermic reaction breaks down the release layer to release the substrate from the semiconductor device. The energy pulse may be an electric charge, a heat pulse, or may be applied from a laser.

Abstract: An assembly comprising a device wafer received in a recess of a carrier wafer. A device wafer comprising a protrusion terminating at an active surface bearing integrated circuitry, the protrusion surrounded by a peripheral flat extending to an outer periphery of the device wafer. A method of wafer thinning using the previously described carrier wafer and device wafer. Various implementations of a carrier wafer having a recess are also disclosed, as are methods of fabrication.

Abstract: A bond chuck having individually-controllable regions, and associated systems and methods are disclosed herein. The bond chuck comprises a plurality of individual regions that are movable relative to one another in a longitudinal direction. In some embodiments, the individual regions include a first region having a first outer surface, and a second region peripheral to the first region and including a second outer surface. The first region is movable in a longitudinal direction to a first position, and the second region is movable in the longitudinal direction to a second position, such that in the second position, the second outer surface of the second region extends longitudinally beyond the first outer surface of the first region. The bond chuck can be positioned proximate a substrate of a semiconductor device such that movement of the first region and/or second region affect a shape of the substrate, which thereby causes an adhesive on the substrate to flow in a lateral, predetermined direction.

Abstract: A bond chuck having individually-controllable regions, and associated systems and methods are disclosed herein. The bond chuck comprises a plurality of individual regions configured to be individually heated independent of one another. In some embodiments, the individual regions include a first region configured to be heated to a first temperature, and a second region peripheral to the first region and configured to be heated to a second temperature different than the first temperature. In some embodiments, the bond chuck further comprises (a) a first coil disposed within the first region and configured to heat the first region to the first temperature, and (b) a second coil disposed within the second region and configured to heat the second region to the second temperature.

Abstract: A semiconductor device assembly can include a first die package comprising a bottom side; a top side; and lateral sides extending between the top and bottom sides. The assembly can include an encapsulant material encapsulating the first die package. In some embodiments, the assembly includes a cooling cavity in the encapsulant material. The cooling cavity can have a first opening; a second opening; and an elongate channel extending from the first opening to the second opening. In some embodiments, the elongate channel surrounds at least two of the lateral sides of the first die package. In some embodiments, the elongate channel is configured to accommodate a cooling fluid.

Abstract: A method of processing a device wafer comprising applying a sacrificial material to a surface of a carrier wafer, adhering a surface of the device wafer to an opposing surface of the carrier wafer, planarizing an exposed surface of the sacrificial material by removing only a portion of a thickness thereof, and planarizing an opposing surface of the device wafer. A wafer assembly is also disclosed.

Abstract: A semiconductor device assembly can include a first die package comprising a bottom side; a top side; and lateral sides extending between the top and bottom sides. The assembly can include an encapsulant material encapsulating the first die package. In some embodiments, the assembly includes a cooling cavity in the encapsulant material. The cooling cavity can have a first opening; a second opening; and an elongate channel extending from the first opening to the second opening. In some embodiments, the elongate channel surrounds at least two of the lateral sides of the first die package. In some embodiments, the elongate channel is configured to accommodate a cooling fluid.

Abstract: A bond chuck having individually-controllable regions, and associated systems and methods are disclosed herein. The bond chuck comprises a plurality of individual regions that are movable relative to one another in a longitudinal direction. In some embodiments, the individual regions include a first region having a first outer surface, and a second region peripheral to the first region and including a second outer surface. The first region is movable in a longitudinal direction to a first position, and the second region is movable in the longitudinal direction to a second position, such that in the second position, the second outer surface of the second region extends longitudinally beyond the first outer surface of the first region. The bond chuck can be positioned proximate a substrate of a semiconductor device such that movement of the first region and/or second region affect a shape of the substrate, which thereby causes an adhesive on the substrate to flow in a lateral, predetermined direction.

Abstract: A bond chuck having individually-controllable regions, and associated systems and methods are disclosed herein. The bond chuck comprises a plurality of individual regions configured to be individually heated independent of one another. In some embodiments, the individual regions include a first region configured to be heated to a first temperature, and a second region peripheral to the first region and configured to be heated to a second temperature different than the first temperature. In some embodiments, the bond chuck further comprises (a) a first coil disposed within the first region and configured to heat the first region to the first temperature, and (b) a second coil disposed within the second region and configured to heat the second region to the second temperature.

Abstract: A semiconductor manufacturing system comprises a laser and a heated bond tip and is configured to bond a die stack in a semiconductor assembly. The semiconductor assembly includes a wafer, manufacture from a material that is optically transparent to a beam emitted by the laser and configured to support a die stack comprising a plurality of semiconductor dies. A metal film is deposited on the wafer and heatable by the beam emitted by the laser. The heated bond tip applies heat and pressure to the die stack, compressing the die stack between the heated bond tip and the metal film and thermally bonding dies in the stack by heat emitted by the heated bond tip and the metal film when the metal film is heated by the beam emitted from the laser.

Abstract: Semiconductor device assemblies may include a carrier wafer and a thermoset adhesive on a surface of the carrier wafer. A metal barrier material may be located on the thermoset adhesive. A thermoplastic adhesive may be located on an opposite side of the metal barrier material from the thermoset adhesive. A device wafer may be located on an opposite side of the thermoplastic material from the metal barrier material. Semiconductor device processing systems may include a carrier wafer having a thermoset adhesive adhered to a surface thereof and a metal barrier material adhered to the thermoset adhesive opposite the carrier wafer. A laser apparatus may be located on an opposite side of the carrier wafer from the metal barrier material and positioned to aim a laser beam through the carrier wafer to impinge on the metal barrier material.

Abstract: A method for processing semiconductor dice comprises removing material from a surface of a semiconductor wafer to create a pocket surrounded by a sidewall at a lateral periphery of the semiconductor wafer, forming a film on a bottom of the pocket and securing semiconductor dice to the film in mutually spaced locations. A dielectric molding material is placed in the pocket over and between the semiconductor dice, material is removed from another surface of the semiconductor wafer to expose the film, bond pads of the semiconductor dice are exposed, redistribution layers in electrical communication with the bond pads of associated semiconductor dice are formed, and the redistribution layers and associated semiconductor dice are singulated along spaces between the semiconductor dice.

Abstract: A semiconductor device assembly having a semiconductor device attached to a substrate with a foil layer on a surface of the substrate. A layer of adhesive connects the substrate to a first surface of the semiconductor device. The semiconductor device assembly enables processing on the second surface of the semiconductor device. An energy pulse may be applied to the foil layer causing an exothermic reaction to the foil layer that releases the substrate from the semiconductor device. The semiconductor device assembly may include a release layer positioned between the foil layer and the layer of adhesive that connects the substrate to the semiconductor device. The heat generated by the exothermic reaction breaks down the release layer to release the substrate from the semiconductor device. The energy pulse may be an electric charge, a heat pulse, or may be applied from a laser.

Abstract: A semiconductor device assembly having a semiconductor device attached to a substrate with a foil layer on a surface of the substrate. A layer of adhesive connects the substrate to a first surface of the semiconductor device. The semiconductor device assembly enables processing on the second surface of the semiconductor device. An energy pulse may be applied to the foil layer causing an exothermic reaction to the foil layer that releases the substrate from the semiconductor device. The semiconductor device assembly may include a release layer positioned between the foil layer and the layer of adhesive that connects the substrate to the semiconductor device. The heat generated by the exothermic reaction breaks down the release layer to release the substrate from the semiconductor device. The energy pulse may be an electric charge, a heat pulse, or may be applied from a laser.

Abstract: Methods of detaching semiconductor device structures from carrier structures may involve directing a laser through a carrier structure comprising a semiconductor material to a barrier material located between the carrier structure and a semiconductor device structure adhere to an opposite side of the barrier material. A bond between the carrier structure and an adhesive material temporarily securing the carrier structure to the semiconductor device structure may be released in response to heating of the barrier material by the laser beam. The carrier structure may be removed from the semiconductor device structure, the barrier material removed, and an adhesive bonding the semiconductor device structure to the barrier material removed.