Abstract: An interposer comprises a semiconductor material and includes cache memory under a location on the interposer for a host device. Memory interface circuitry may also be located under one or more locations on the interposer for memory devices. Microelectronic device assemblies incorporating such an interposer and comprising a host device and multiple memory devices are also disclosed, as are methods of fabricating such microelectronic device assemblies.

Abstract: A packaging technology in which power switching elements, such as field-effect transistors (FETs), can be oriented in a vertical position relative to the printed circuit board (PCB) on which the product is mounted. The power die including the switching element(s) can essentially stand “on end” so that they take up very little PCB area. Multiple dies can be positioned this way, and the dies can be attached to a heat sink structure, which is designed to take the heat generated by the dies onto the top of the package. The heat sink structure can be attached to a structure to route the power and analog signals properly to the desired pins/leads/balls of the finished product. Using these techniques can result in a significant increase in the power density (both PCB space and solution volume) of power switching elements, e.g., FETs.

Abstract: A semiconductor device includes a dielectric interposer, a first interconnection layer, an electronic component, a plurality of electrical conductors and a plurality of conductive structures. The dielectric interposer has a first surface and a second surface opposite to the first surface. The first interconnection layer is over the first surface of the dielectric interposer. The electronic component is over and electrically connected to the first interconnection layer. The electrical conductors are over the second surface of the dielectric interposer. The conductive structures are through the dielectric interposer, wherein the conductive structures are electrically connected to the first interconnection layer and the electrical conductors.

Abstract: The semiconductor device includes a substrate including an integrated circuit and a contact that are electrically connected to each other, an insulation layer covering the substrate and including metal lines, and a through electrode electrically connected to the integrated circuit. The insulation layer includes an interlayer dielectric layer on the substrate and an intermetal dielectric layer on the interlayer dielectric layer. The metal lines include a first metal line in the interlayer dielectric layer and electrically connected to the contact, and a plurality of second metal lines in the intermetal dielectric layer and electrically connected to the first metal line and the through electrode. The through electrode includes a top surface higher than a top surface of the contact.

Abstract: Microelectronic assemblies, and related devices and methods, are disclosed herein. For example, in some embodiments, a microelectronic assembly may include a package substrate having a first surface and an opposing second surface, and a die secured to the package substrate, wherein the die has a first surface and an opposing second surface, the die has first conductive contacts at the first surface and second conductive contacts at the second surface, and the first conductive contacts are coupled to conductive pathways in the package substrate by first non-solder interconnects.

Abstract: FET designs that exhibit low leakage in the presence of the edge transistor phenomenon. Embodiments includes nFET designs in which the work function ?MF of the gate structure overlying the edge transistors of the nFET is increased by forming extra P+ implant regions within at least a portion of the gate structure, thereby increasing the Vt of the edge transistors to a level that may exceed the Vt of the central conduction channel of the nFET. In some embodiments, the gate structure of the nFET is modified to increase or “flare” the effective channel length of the edge transistors relative to the length of the central conduction channel of the FET. Other methods of changing the work function ?MF of the gate structure overlying the edge transistors are also disclosed. The methods may be adapted to fabricating pFETs by reversing or substituting material types.

Abstract: Microelectronic assemblies, related devices and methods, are disclosed herein. In some embodiments, a microelectronic assembly may include a package substrate having a first surface and an opposing second surface; a first die having a first surface and an opposing second surface embedded in a first dielectric layer, where the first surface of the first die is coupled to the second surface of the package substrate by first interconnects; a second die having a first surface and an opposing second surface embedded in a second dielectric layer, where the first surface of the second die is coupled to the second surface of the first die by second interconnects; and a third die having a first surface and an opposing second surface embedded in a third dielectric layer, where the first surface of the third die is coupled to the second surface of the second die by third interconnects.

Abstract: A method includes performing a first laser shot on a first portion of a top surface of a first package component. The first package component is over a second package component, and a first solder region between the first package component and the second package component is reflowed by the first laser shot. After the first laser shot, a second laser shot is performed on a second portion of the top surface of the first package component. A second solder region between the first package component and the second package component is reflowed by the second laser shot.

Abstract: A semiconductor structure is provided. The semiconductor structure includes a first semiconductor device. The first semiconductor device includes a first bonding layer formed below a first substrate, a first bonding via formed through the first oxide layer and the first bonding layer, a first dummy pad formed in the first bonding layer. The semiconductor structure includes a second semiconductor device. The second semiconductor device includes a second bonding layer formed over a second substrate, a second bonding via formed through the second bonding layer, and a second dummy pad formed in the second bonding layer. The semiconductor structure includes a bonding structure between the first substrate and the second substrate, wherein the bonding structure includes the first bonding via bonded to the second bonding via and the first dummy pad bonded to the second dummy pad.

Abstract: A semiconductor package structure, including a circuit substrate, at least two chips, an encapsulant, and a redistribution layer, is provided. The circuit substrate has a first surface and a second surface opposite to the first surface. The at least two chips are disposed on the first surface. Each of the at least two chips has an active surface facing the circuit substrate and includes multiple first conductive connectors and multiple second conductive connectors disposed on the active surface. A pitch of the first conductive connectors is less than a pitch of the second conductive connectors. The encapsulant encapsulates the at least two chips. The redistribution layer is located on the second surface. The first conductive connectors are electrically connected to the redistribution layer by the circuit substrate. The second conductive connectors are electrically connected to the circuit substrate. A manufacturing method of a semiconductor package structure is also provided.

Abstract: A semiconductor device includes a semiconductor substrate, an interconnect structure, and a permalloy device. The interconnect structure is disposed over the semiconductor substrate. The interconnect structure includes a conductive coil. The conductive coil includes horizontally-extending metal lines, and vertically-extending vias electrically connecting the metal lines. The permalloy device is disposed in the interconnector structure and wound around by the conductive coil and insulated by the conductive coil, wherein the permalloy device and the conductive coil in combination define an inductor, and the permalloy device serves as a magnetic core of the inductor.

Abstract: A semiconductor device has a substrate and a plurality of bond wires is disposed in a pattern across on the substrate. The pattern of bond wires can be a plurality of rows of bond wires. A plurality of electrical components is disposed over the substrate as an SIP module. An encapsulant is deposited over the substrate, electrical components, and bond wire. An opening is formed in the encapsulant extending to the bond wire. The opening can be a trench extending across the bond wires disposed on the substrate, or a plurality of openings individually exposing each of a plurality of bond wires. A conductive material is disposed in the opening. A shielding layer is formed over the encapsulant and in contact with the conductive material. The shielding layer, conductive material, and bond wires reduce the effects of EMI, RFI, and other inter-device interference.

Abstract: Apparatuses, systems and methods associated with a substrate assembly with an encapsulated magnetic feature for an inductor are disclosed herein. In embodiments, a substrate assembly may include a base substrate, a magnetic feature encapsulated within the base substrate, and a coil, wherein a portion of the coil extends through the magnetic feature. Other embodiments may be described and/or claimed.

Abstract: A package-on-package type package includes a lower semiconductor package and an upper semiconductor package. The lower semiconductor package includes a first semiconductor device including a through electrode, a second semiconductor device disposed on the first semiconductor device and including a second through electrode electrically connected to the first through electrode, a first molding member covering a sidewall of at least one of the first semiconductor device and the second semiconductor device, a second molding member covering a sidewall of the first molding member, and an upper redistribution layer disposed on the second semiconductor device and electrically connected to the second through electrode.

Abstract: A method includes performing a first light-exposure and a second a second light-exposure on a photo resist. The first light-exposure is performed using a first lithograph mask, which covers a first portion of the photo resist. The first portion of the photo resist has a first strip portion exposed in the first light-exposure. The second light-exposure is performed using a second lithograph mask, which covers a second portion of the photo resist. The second portion of the photo resist has a second strip portion exposed in the second light-exposure. The first strip portion and the second strip portion have an overlapping portion that is double exposed. The method further includes developing the photo resist to remove the first strip portion and the second strip portion, etching a dielectric layer underlying the photo resist to form a trench, and filling the trench with a conductive feature.

Abstract: A method for forming a via in a semiconductor device and a semiconductor device including the via are disclosed. In an embodiment, the method may include bonding a first terminal and a second terminal of a first substrate to a third terminal and a fourth terminal of a second substrate; separating the first substrate to form a first component device and a second component device; forming a gap fill material over the first component device, the second component device, and the second substrate; forming a conductive via extending from a top surface of the gap fill material to a fifth terminal of the second substrate; and forming a top terminal over a top surface of the first component device, the top terminal connecting the first component device to the fifth terminal of the second substrate through the conductive via.

Abstract: A semiconductor manufacturing device has a cooling pad with a plurality of movable pins. The cooling pad includes a fluid pathway and a plurality of springs disposed in the fluid pathway. Each of the plurality of springs is disposed under a respective movable pin. A substrate includes an electrical component disposed over a surface of the substrate. The substrate is disposed over the cooling pad with the electrical component oriented toward the cooling pad. A force is applied to the substrate to compress the springs. At least one of the movable pins contacts the substrate. A cooling fluid is disposed through the fluid pathway.

Abstract: Methods and structures includes providing a substrate, forming a prelayer over a substrate, forming a barrier layer over the prelayer, and forming a channel layer over the barrier layer. Forming the prelayer may include growing the prelayer at a graded temperature. Forming the barrier layer is such that the barrier layer may include GaAs or InGaAs. Forming the channel layer is such that the channel layer may include InAs or an Sb-based heterostructure. Thereby structures are formed.

Abstract: Aspects of the disclosure relate to thermal management of devices, such as mobile devices configured for wireless communication in wireless communication networks. A device includes a plurality of electronic components. An electromagnetic interference (EMI) shield is disposed on the electronic components, and a plurality of EMI gaskets are disposed between the electronic components. Each of the EMI gaskets surrounds a respective one of the plurality of electronic components. An evaporative cooler device embedded within the EMI shield is configured to transfer heat away from at least a portion of the electronic components.

Abstract: Described herein is a FinFET device in which epitaxial layers of semiconductor material are formed in source/drain regions on fin portions. The fin portions can be located within a dielectric layer that is deposited on a semiconductor substrate. Surfaces of the fin portions can be oriented in the {100} lattice plane of the crystalline material of the fin portions, providing for good epitaxial growth. Further described are methods for forming the FinFET device.