Abstract: This patent application relates to methods and apparatus for temperature modification and reduction of contamination in bonding stacked microelectronic devices with heat applied from a bond head of a thermocompression bonding tool. The stack is substantially enclosed within a skirt carried by the bond head to reduce heat loss and contaminants from the stack, and heat may be added from the skirt.

Abstract: Processes for adjusting dimensions of dielectric bond line materials in stacks of microelectronic components to prevent extrusion of the dielectric bond line materials beyond component peripheries during thermocompression bonding by patterning the materials with boundary portions inset from component peripheries, or employing an inset dielectric material surrounded by another solidified dielectric material. Related material films, articles and assemblies are also disclosed.

Abstract: Methods for reducing heat transfer in semiconductor devices, and associated systems and devices, are described herein. In some embodiments, a method of manufacturing a semiconductor device includes forming a channel in a region of a substrate between a first die stack and a second die stack. The first die stack includes a plurality of first dies attached to each other by first film layers and the second die stack includes a plurality of second dies attached to each other by second film layers. The channel extends entirely through a thickness of the substrate. The method also includes applying heat to the first die stack to cure the first film layers. The channel reduces heat transfer from the first die stack to the second die stack.

Abstract: Methods for reducing heat transfer in semiconductor devices, and associated systems and devices, are described herein. In some embodiments, a method of manufacturing a semiconductor device includes forming a channel in a region of a substrate between a first die stack and a second die stack. The first die stack includes a plurality of first dies attached to each other by first film layers and the second die stack includes a plurality of second dies attached to each other by second film layers. The channel extends entirely through a thickness of the substrate. The method also includes applying heat to the first die stack to cure the first film layers. The channel reduces heat transfer from the first die stack to the second die stack.

Abstract: This patent application relates to methods and apparatus for temperature modification within a stack of microelectronic devices for mutual collective bonding of the microelectronic devices, and to related substrates and assemblies.

Abstract: Singulated integrated circuit (IC) dice are provided. The singulated IC dice are positioned on dicing tape to provide open space between sides of adjacent singulated IC dice. An underfill layer and a protective cover film is disposed above the singulated IC dice and the open space between the sides of the adjacent singulated IC dice. The underfill layer and the protective cover film include one or more photodefinable materials. An exposure operation is performed to produce a pattern on the underfill layer and the protective cover film. Based on the pattern, the underfill layer and the protective cover film is removed at areas above the open space between the sides of the adjacent singulated IC dice to create portions of the underfill layer and portions of the protective cover film that are disposed above the singulated IC dice.

Abstract: A bond tip for thermocompression bonding a bottom surface includes a die contact area and a low surface energy material covering at least a portion of the bottom surface. The low surface energy material may cover substantially all of the bottom surface, or only a peripheral portion surrounding the die contact area. The die contact area may be recessed with respect to the peripheral portion a depth at least as great as a thickness of a semiconductor die to be received in the recessed die contact area. A method of thermocompression bonding is also disclosed.

Abstract: A semiconductor device assembly is provided. The assembly includes a first package element and a second package element disposed over the first package element. The assembly further includes a plurality of die support structures between the first and second package elements, wherein each of the plurality of die support structures has a first height, a lower portion surface-mounted to the first package element and an upper portion in contact with the second package element. The assembly further includes a plurality of interconnects between the first and second package elements, wherein each of the plurality of interconnects includes a conductive pillar having a second height, a conductive pad, and a bond material with a solder joint thickness between the conductive pillar and the conductive pad. The first height is about equal to a sum of the solder joint thickness and the second height.

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

Abstract: Methods for releasing thinned semiconductor dies from a mount tape and associated apparatuses are disclosed. In one embodiment, a sacrificial layer may be disposed at a back side of thinned substrate including semiconductor dies. The sacrificial layer includes materials soluble in contact with a fluid (and/or vapor). A sheet of perforated mount tape may be attached to the sacrificial layer and an ejection component may be provided under a target semiconductor die to be released. The ejection component is configured to create a locally confined puddle of the fluid under the target semiconductor die such that the sacrificial layer is removed to release the target semiconductor die from the mount tape. Further, a support component may be provided to pick up the target semiconductor die after the target semiconductor die is released from the mount tape.

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 device assembly that includes a semiconductor device positioned over a substrate with a number of electrical interconnections formed between the semiconductor device and the substrate. The surface of the substrate includes a plurality of discrete solder mask standoffs that extend towards the semiconductor device. A thermal compression bonding process is used to melt solder to form the electrical interconnects, which lowers the semiconductor device to contact and be supported by the plurality of discrete solder mask standoffs. The solder mask standoffs permit the application of a higher pressure during the bonding process than using traditional solder masks. The solder mask standoffs may have various polygonal or non-polygonal shapes and may be positioned in pattern to protect sensitive areas of the semiconductor device and/or the substrate. The solder mask standoffs may be an elongated shape that protects areas of the semiconductor device and/or substrate.

Abstract: A semiconductor device assembly is provided. The assembly includes a first semiconductor die and a second semiconductor die disposed over the first semiconductor die. The assembly further includes a plurality of die support structures between the first and second semiconductor dies and a plurality of interconnects between the first and second semiconductor dies. Each of the plurality of die support structures includes a stand-off pillar and a stand-off pad having a first bond material with a first solder joint thickness between them. Each of the plurality of interconnects includes a conductive pillar and a conductive pad having a second bond material with a second solder joint thickness between them. The first solder joint thickness is less than the second solder joint thickness.

Abstract: A bond tip for thermocompression bonding a bottom surface includes a die contact area and a low surface energy material covering at least a portion of the bottom surface. The low surface energy material may cover substantially all of the bottom surface, or only a peripheral portion surrounding the die contact area. The die contact area may be recessed with respect to the peripheral portion a depth at least as great as a thickness of a semiconductor die to be received in the recessed die contact area. A method of thermocompression bonding is also disclosed.

Abstract: Systems and methods for controlling contamination during thermocompression bonding are provided herein. The tool generally includes a bondhead having a first channel extending in a lateral direction from a first port along a second side toward a perimeter of the bondhead. In several examples, the bondhead includes a second channel fluidly coupled to a second port and extending in a lateral direction along an inset surface of the bondhead, where the second channel at least partially surrounds the first channel. In other examples, the tool includes a vacuum manifold having a vacuum opening positioned laterally outward from the bondhead. A first flow unit is coupled to the first channel and is configured to withdraw air. A second flow unit is coupled to the second port or the manifold to withdraw fluid and prevent outgas sing bonding materials from entering the first channel, depositing on the bondhead, and/or contaminating neighboring semiconductor components.

Abstract: Methods for fabricating microelectronic device assemblies, the method comprising providing mutually spaced stacks of microelectronic devices on a substrate and substantially concurrently encapsulating the stacks of microelectronic devices on the substrate and gang bonding mutually aligned conductive elements of vertically adjacent microelectronic devices. Compression molding apparatus for implementing the methods, and resulting microelectronic device assemblies are also disclosed.

Abstract: A semiconductor device, semiconductor device assembly, and method of forming a semiconductor device assembly that includes moisture impermeable layer. The assembly includes a first substrate and a second substrate electrically connected to a surface of the first substrate. The assembly includes a layer between the two substrates with the moisture impermeable layer between the layer and the surface of the first substrate. The layer may be non-conductive film, die attach film, capillary underfill, or the like. A portion of the surface of the first substrate may include a solder mask between the moisture impermeable layer and the first substrate. The moisture impermeable layer prevents, or at least inhibits, moisture within the first substrate from potentially creating voids in the layer. The moisture impermeably layer may be a polyimide, a polyimide-like material, an epoxy, an epoxy-acrylate, parylene, vinyltriethoxysilane, or combination thereof.

Abstract: A semiconductor device assembly is provided. The assembly includes a first package element and a second package element disposed over the first package element. The assembly further includes a plurality of die support structures between the first and second package elements, wherein each of the plurality of die support structures has a first height, a lower portion surface-mounted to the first package element and an upper portion in contact with the second package element. The assembly further includes a plurality of interconnects between the first and second package elements, wherein each of the plurality of interconnects includes a conductive pillar having a second height, a conductive pad, and a bond material with a solder joint thickness between the conductive pillar and the conductive pad. The first height is about equal to a sum of the solder joint thickness and the second height.

Abstract: Methods for fabricating microelectronic device assemblies, the method comprising providing mutually spaced stacks of microelectronic devices on a substrate and substantially concurrently encapsulating the stacks of microelectronic devices on the substrate and gang bonding mutually aligned conductive elements of vertically adjacent microelectronic devices. Compression molding apparatus for implementing the methods, and resulting microelectronic device assemblies are also disclosed.

Abstract: A semiconductor device assembly is provided. The assembly includes a first semiconductor die and a second semiconductor die disposed over the first semiconductor die. The assembly further includes a plurality of die support structures between the first and second semiconductor dies and a plurality of interconnects between the first and second semiconductor dies. Each of the plurality of die support structures includes a stand-off pillar and a stand-off pad having a first bond material with a first solder joint thickness between them. Each of the plurality of interconnects includes a conductive pillar and a conductive pad having a second bond material with a second solder joint thickness between them. The first solder joint thickness is less than the second solder joint thickness.