Abstract: An embodiment device package includes a fan-out redistribution layer (RDL), a device over and bonded to the fan-out RDL, and a molding compound over the fan-out RDL and extending along sidewalls of the device. The device includes a first functional tier having a first metallization layer and a second functional tier having a second metallization layer. The second functional tier is bonded to the first functional tier. The device further includes an interconnect structure electrically connecting the first metallization layer to the second metallization layer. The interconnect structure includes an inter-tier via (ITV) at least partially disposed in both the first functional tier and the second functional tier, and the ITV contacts the first metallization layer.

Abstract: A method of multi-chip wafer level packaging comprises attaching a first semiconductor die to a top side of a wafer, forming a first reconfigured wafer by embedding the first semiconductor die into a first photo-sensitive material layer, forming a first group of through assembly vias in the first photo-sensitive material layer, attaching a second semiconductor die to the first photo-sensitive material layer, forming a second photo-sensitive material layer on top of the first photo-sensitive material layer, wherein the second semiconductor die is embedded in the second photo-sensitive material layer and forming a second group of through assembly vias in the second photo-sensitive material layer.

Abstract: A method includes forming a plurality of metal posts. The plurality of metal posts is interconnected to form a metal-post row by weak portions between neighboring ones of the plurality of metal posts. The weak portions include a same metal as the plurality of metal posts. A majority of each of the plurality of metal posts is separated from respective neighboring ones of the plurality of metal posts. An end portion of each of the plurality of metal posts is plated with a metal. The plurality of metal posts is disposed into a metal post-storage. The method further includes retrieving one of the metal posts from a metal-post storage, and bonding the one of the metal posts on a metal pad.

Abstract: A stacked package includes a substrate, and a first structure bonded to the substrate. The first structure has a plurality of bumps, and a first hydrophilic coating is on sidewalls of the first structure. The stacked package further includes a second structure bonded to the plurality of bumps. The first hydrophilic coating is on sidewalls of the second structure. The first structure is between the second structure and the substrate. The stacked package further includes a housing, wherein the housing defines a volume enclosing the first structure and the second structure. A second hydrophilic coating is on sidewalls of an inner surface of the housing. The stacked package further includes a cooling fluid within the volume enclosing the first structure and the second structure. A top surface of the cooling fluid is above a top surface of the second structure.

Abstract: A conductive interconnect structure includes a contact pad; a conductive body connected to the contact pad at a first end; and a conductive layer positioned on a second end of the conductive body. The conductive body has a longitudinal direction perpendicular to a surface of the contact pad. The conductive body has an average grain size (a) on a cross sectional plane (Plane A) whose normal is perpendicular to the longitudinal direction of the conductive body. The conductive layer has an average grain size (b) on Plane A. The conductive body and the conductive layer are composed of same material, and the average grain size (a) is greater than the average grain size (b).

Abstract: An embodiment device package includes a fan-out redistribution layer (RDL), a device over and bonded to the fan-out RDL, and a molding compound over the fan-out RDL and extending along sidewalls of the device. The device includes a first functional tier having a first metallization layer and a second functional tier having a second metallization layer. The second functional tier is bonded to the first functional tier. The device further includes an interconnect structure electrically connecting the first metallization layer to the second metallization layer. The interconnect structure includes an inter-tier via (ITV) at least partially disposed in both the first functional tier and the second functional tier, and the ITV contacts the first metallization layer.

Abstract: A method includes forming a plurality of metal posts. The plurality of metal posts is interconnected to form a metal-post row by weak portions between neighboring ones of the plurality of metal posts. The weak portions include a same metal as the plurality of metal posts. A majority of each of the plurality of metal posts is separated from respective neighboring ones of the plurality of metal posts. An end portion of each of the plurality of metal posts is plated with a metal. The plurality of metal posts is disposed into a metal post-storage. The method further includes retrieving one of the metal posts from a metal-post storage, and bonding the one of the metal posts on a metal pad.

Abstract: A semiconductor device includes an under-bump metallization (UBM) layer over a substrate. The semiconductor device also includes a copper-containing layer having a base portion over the UBM layer. The semiconductor device further includes a solder bump over the UBM layer and over the copper-containing layer. The base portion is embedded in the solder bump. The copper-containing layer has a cylindrical shape and includes at least two segments separated by at least two openings. A first total area (A) of the at least two openings is greater than about 3% of a second total area (B) of the at least two segments. The first total area (A) is less than about 70% of the second total area (B) of the at least two segments.

Abstract: A multi-chip semiconductor device comprises a thermally enhanced structure, a first semiconductor chip, a second semiconductor chip, an encapsulation layer formed on top of the first semiconductor chip and the second semiconductor chip. The multi-chip semiconductor device further comprises a plurality of thermal vias formed in the encapsulation layer. The thermally enhanced structure comprises a heat sink block attached to a first semiconductor die. The heat sink block may further comprise a variety of thermal vias and thermal openings. By employing the thermal enhanced structure, the thermal performance of the multi-chip semiconductor device can be improved.

Abstract: Some embodiments of the present disclosure relate to an apparatus and method to form a pattern of solder bumps. A solder paste is applied a plate comprising a pattern of holes, where each hole is partially filled by a piston attached to a movable stage. The remainder of the holes are filled by applying a force to the solder paste with a first solder paste application tool. A second solder paste application tool then removes excess paste from the front surface of the plate. The solder paste is then disposed onto a surface of a substrate by moving the movable stage, which fills a larger portion of each hole with a piston, forces the solder paste out of each hole, and forms pattern of solder paste on the surface of the substrate. The pattern of solder paste is then subjected to additional processing to form a pattern of solder bumps.

Abstract: A semiconductor die includes a crack stopper on an under-bump metallization (UBM) layer. The crack stopper is in the shape of hollow cylinder with at least two openings.

Abstract: A multi-chip semiconductor device comprises a thermally enhanced structure, a first semiconductor chip, a second semiconductor chip, an encapsulation layer formed on top of the first semiconductor chip and the second semiconductor chip. The multi-chip semiconductor device further comprises a plurality of thermal vias formed in the encapsulation layer. The thermally enhanced structure comprises a heat sink block attached to a first semiconductor die. The heat sink block may further comprise a variety of thermal vias and thermal openings. By employing the thermal enhanced structure, the thermal performance of the multi-chip semiconductor device can be improved.

Abstract: An embodiment device package includes a fan-out redistribution layer (RDL), a device over and bonded to the fan-out RDL, and a molding compound over the fan-out RDL and extending along sidewalls of the device. The device includes a first functional tier having a first metallization layer and a second functional tier having a second metallization layer. The second functional tier is bonded to the first functional tier. The device further includes an interconnect structure electrically connecting the first metallization layer to the second metallization layer. The interconnect structure includes an inter-tier via (ITV) at least partially disposed in both the first functional tier and the second functional tier, and the ITV contacts the first metallization layer.

Abstract: Disclosed embodiments include wire joints and methods of forming wire joints that can enable realization of fine pitch joints and collapse control for various packages. A first embodiment is a structure comprising a first substrate, a second substrate, and a wire joint. The first substrate comprises a first bonding surface, and the second substrate comprises a second bonding surface. The first bonding surface is opposite and faces the second bonding surface. The wire joint is attached to and between the first bonding surface and the second bonding surface.

Abstract: Non-planar transistors and methods of fabrication thereof are described. In an embodiment, a method of forming a non-planar transistor includes forming a channel region on a first portion of a semiconductor fin, the semiconductor fin having a top surface and sidewalls. A gate electrode is formed over the channel region of the semiconductor fin, and an in-situ doped semiconductor layer is grown on the top surface and the sidewalls of the semiconductor fin on opposing sides of the gate electrode using a selective epitaxial growth process. At least a part of the doped semiconductor layer is converted to form a dopant rich region.

Abstract: Some embodiments of the present disclosure relate to an apparatus and method to form a pattern of solder bumps. A solder paste is applied a plate comprising a pattern of holes, where each hole is partially filled by a piston attached to a movable stage. The remainder of the holes are filled by applying a force to the solder paste with a first solder paste application tool. A second solder paste application tool then removes excess paste from the front surface of the plate. The solder paste is then disposed onto a surface of a substrate by moving the movable stage, which fills a larger portion of each hole with a piston, forces the solder paste out of each hole, and forms pattern of solder paste on the surface of the substrate. The pattern of solder paste is then subjected to additional processing to form a pattern of solder bumps.

Abstract: A wafer-level pulling method includes securing a top holder to a plurality of chips; and securing a bottom holder to a wafer, wherein the plurality of chips are bonded to the wafer by a plurality of solder bumps. The wafer-level pulling method further includes softening the plurality of solder bumps; and stretching the plurality of softened solder bumps.

Abstract: A conductive interconnect structure includes a contact pad; a conductive body connected to the contact pad at a first end; and a conductive layer positioned on a second end of the conductive body. The conductive body has a longitudinal direction perpendicular to a surface of the contact pad. The conductive body has an average grain size (a) on a cross sectional plane (Plane A) whose normal is perpendicular to the longitudinal direction of the conductive body. The conductive layer has an average grain size (b) on Plane A. The conductive body and the conductive layer are composed of same material, and the average grain size (a) is greater than the average grain size (b).

Abstract: A stacked package includes a substrate, and a first structure bonded to the substrate. The first structure has a plurality of bumps, and a first hydrophilic coating is on sidewalls of the first structure. The stacked package further includes a second structure bonded to the plurality of bumps. The first hydrophilic coating is on sidewalls of the second structure. The first structure is between the second structure and the substrate. The stacked package further includes a housing, wherein the housing defines a volume enclosing the first structure and the second structure. A second hydrophilic coating is on sidewalls of an inner surface of the housing. The stacked package further includes a cooling fluid within the volume enclosing the first structure and the second structure. A top surface of the cooling fluid is above a top surface of the second structure.

Abstract: Disclosed herein is a system and method for mounting packages by forming one or more wire loop interconnects, optionally, with a wirebonder, and mounting the interconnects to a mounting pad on a first substrate. A first and second stud ball may each have at least one flat surface be disposed on a single mounting pad, and a wire having a bend region and forming a loop may be disposed between the stud balls. The stud balls may be formed from a deformed mouthing node formed on a wire. The loop may be mounted on a mounting pad on a first substrate and a second substrate may be mounted on the loop via a conductive material such as solder.