A method of directly transferring a first semiconductor device die to a substrate includes loading a wafer tape into a first frame, loading a substrate into a second frame, arranging at least one of the first frame or the second frame such that a surface of the substrate is adjacent to a first side of the wafer tape, and orienting a needle to a position adjacent to a second side of the wafer tape, the needle extending in a direction toward the wafer tape. The method also includes activating a needle actuator connected to the needle to move the needle to a die transfer position at which the needle contacts the second side of the wafer tape to press the first semiconductor device die into contact with the second semiconductor device die.

In a method for manufacturing a semiconductor device, a plurality of first provisional fixing portions are supplied on a front surface of a substrate such that the plurality of first provisional fixing portions are spaced from each other and thus dispersed. A first solder layer processed into a plate to be a first soldering portion is disposed in contact with the plurality of first provisional fixing portions. A semiconductor chip is disposed on the first solder layer. In addition a conductive member in the form of a flat plate is disposed thereon via a second provisional fixing portion and a second solder layer. A reflow process is performed to solder the substrate, the semiconductor chip and the conductive member together.

Generally described, one or more embodiments are directed to a leadframe package having a plurality of leads, a die pad, a semiconductor die coupled to the die pad, and encapsulation material. An inner portion of the die pad includes a perimeter portion that includes a plurality of protrusions that are spaced apart from each other. The protrusions aid in locking the die pad in the encapsulation material. The plurality of leads includes upper portions and base portions. The base portion of the plurality of leads are offset (or staggered) relative to the plurality of protrusions of the die pad. In particular, the base portions extend longitudinally toward the die pad and are located between respective protrusions. The upper portions of the leads include lead locks that extend beyond the base portions in a direction of adjacent leads. The lead locks and the protrusion in the die pad aid in locking the leads and the die pad in the encapsulation material.

A semiconductor assembly comprises a first device, a second device, a passivation layer and an interconnect structure. The first device comprises a first top metal layer. The second device comprises a second bottom metal layer. The passivation layer is disposed on the second device. The interconnect structure electrically couples the first device to the second device, wherein the interconnect structure comprises a head member, a first leg and a second leg. The head member is disposed on the passivation layer. The first leg penetrates through the passivation layer and the second device, wherein the first leg connects the head member to the first top metal layer. The second leg penetrates through the passivation layer and extends into the second device to connect the head member to the second bottom metal layer. The first leg and the second leg comprise a top portion, an intermediate portion and a bottom portion.

Discontinuous bonds for semiconductor devices are disclosed herein. A device in accordance with a particular embodiment includes a first substrate and a second substrate, with at least one of the first substrate and the second substrate having a plurality of solid-state transducers. The second substrate can include a plurality of projections and a plurality of intermediate regions and can be bonded to the first substrate with a discontinuous bond. Individual solid-state transducers can be disposed at least partially within corresponding intermediate regions and the discontinuous bond can include bonding material bonding the individual solid-state transducers to blind ends of corresponding intermediate regions. Associated methods and systems of discontinuous bonds for semiconductor devices are disclosed herein.

Disclosed is a semiconductor package including a first semiconductor chip on a substrate, a second semiconductor chip on the substrate and laterally spaced apart from the first semiconductor chip, a dummy chip on the first semiconductor chip, and a dielectric layer between the first semiconductor chip and the dummy chip. A top surface of the first semiconductor chip may be lower than a top surface of the second semiconductor chip. The dielectric layer may include an inorganic dielectric material.

The invention provides methods and devices for fabricating printable semiconductor elements and assembling printable semiconductor elements onto substrate surfaces. Methods, devices and device components of the present invention are capable of generating a wide range of flexible electronic and optoelectronic devices and arrays of devices on substrates comprising polymeric materials. The present invention also provides stretchable semiconductor structures and stretchable electronic devices capable of good performance in stretched configurations.

Embodiments of the present disclosure include method for sequentially mounting multiple semiconductor devices onto a substrate having a composite metal structure on both the semiconductor devices and the substrate for improved process tolerance and reduced device distances without thermal interference. The mounting process causes “selective” intermixing between the metal layers on the devices and the substrate and increases the melting point of the resulting alloy materials.

A method of forming a microelectronic device comprises forming a first microelectronic device structure comprising a first semiconductor structure, a first isolation material over the first semiconductor structure, and first conductive routing structures over the first semiconductor structure and surrounded by the first isolation material. A second microelectronic device structure comprising a second semiconductor structure and a second isolation material over the second semiconductor structure is formed. The second isolation material is bonded to the first isolation material to attach the second microelectronic device structure to the first microelectronic device structure. Memory cells comprising portions of the second semiconductor structure are formed after attaching the second microelectronic device structure to the first microelectronic device structure. Control logic devices including transistors comprising portions of the first semiconductor structure are formed after forming the memory cells. Microelectronic devices, electronic systems, and additional methods are also described.

Embodiments include forming an interposer having reinforcing structures disposed in a core layer of the interposer. The interposer may be attached to a package device by electrical connectors. The reinforcing structures provide rigidity and thermal dissipation for the package device. Some embodiments may include an interposer with an opening in an upper core layer of the interposer to a recessed bond pad. Some embodiments may also use connectors between the interposer and the package device where a solder material connected to the interposer surrounds a metal pillar connected to the package device.