Electronic devices are formed on donor substrates and transferred to carrier substrates by forming bonding regions on the electronic devices and bonding the bonding regions to a carrier substrate. The transfer process may include forming anchors and removing sacrificial regions.

A semiconductor structure includes a functional die, a dummy die, a conductive feature, a seal ring and an alignment mark. The dummy die is electrically isolated from the functional die. The conductive feature is electrically connected to the functional die. The seal ring is disposed aside the conductive feature. The alignment mark is disposed between the seal ring and the conductive feature, and the alignment mark is electrically isolated from the dummy die, the conductive feature and the seal ring.

A semiconductor device has a photonic semiconductor die. The photonic semiconductor die is disposed on a carrier with a photonic circuit of the photonic semiconductor die oriented toward the carrier. An e-bar is disposed on the carrier. An encapsulant is deposited over the photonic semiconductor die and e-bar. A first surface of the encapsulant is backgrinded to expose the e-bar. A first build-up interconnect structure is formed over the first surface of the encapsulant. A second build-up interconnect structure is formed over a second surface of the encapsulant. The photonic circuit is exposed through an opening of the second build-up interconnect structure.

Methods, systems, and devices for manufacturing technique for mechanical debonding of a carrier wafer from other structures in a stacked semiconductor system are described. The carrier wafer may include a first bonding layer that includes a first plurality of cavities. The stacked semiconductor system may also include a device wafer with a second bonding layer that is fusion bonded with the first bonding layer of the carrier wafer. The second bonding layer of the device wafer may include a second plurality of cavities.

Stacked semiconductor packages with features to mitigate trace exposer and associated systems and methods are disclosed herein. In some embodiments, the stacked semiconductor package includes a base substrate, a stack of dies carried by the base substrate, and a mold material deposited at least partially encapsulating the stack of dies. The base substrate can include an active surface and a back surface opposite the active surface. Further, the active surface can include one or more cuts into a peripheral portion of the active surface (e.g., stepped structures at the peripheral edges of the base substrate). The base substrate can also include a plurality of bond pads carried by the active surface over the peripheral portion. Still further, the mold material can fill each of the one or more cuts in the active surface, thereby insulating the bond pads from exposure at a sidewall of the stacked semiconductor package.

Disclosed are embodiments of a semiconductor package. The semiconductor package may include: a first substrate; a chip stack on the first substrate, wherein the chip stack comprises one or more semiconductor chips that are stacked to be inclined at a first angle relative to a top surface of the first substrate; a tilt support structure, wherein the tilt support structure is between a first portion of the chip stack and the first substrate; and an anti-slip structure in contact with an end portion of the chip stack.

A package and method is disclosed. In one example, the package comprises a carrier comprising a component mounting area from which a tie bar extends, the tie bar being configured for being clamped by an encapsulation tool pin during encapsulation, an electronic component mounted on the component mounting area, and an encapsulant encapsulating at least part of the electronic component and at least part of the carrier, wherein a sidewall of the package has a step between a first vertical sidewall section and a second vertical sidewall section; wherein the first vertical sidewall section has a notch in the encapsulant and a part of the second vertical sidewall section exposes the tie bar.

A method for producing a molded electronic devices includes providing a first metallic frame including a plurality of die pads and a plurality of first connectors that hold the die pads in place. A vertical power semiconductor die is attached to each die pad. One or more second metallic frames are vertically aligned with the first metallic frame. Each second metallic frame includes a plurality of first contact pads and a plurality of second connectors that hold the first contact pads in place. Each of the first contact pads is attached to a load terminal of one of the vertical power semiconductor dies without any direct physical or electrical connection between the first metallic frame and the second metallic frame. The vertical power semiconductor dies are encapsulated in a mold compound. The first connectors and the second connectors are severed to yield individual molded electronic devices.

A structure is disclosed. The structure can include a first processor die, a second processor die, a first memory unit, and a connecting element. The second processor die can be laterally spaced from the first processor die. The first memory unit can be disposed vertically above the first processor die. The connecting element can be disposed vertically to the first processor die and the second processor die. The connecting element can include a conductor electrically connecting the first processor die and the second processor die.

A semiconductor package may include a base chip, at least one chip stack module on the base chip, and a sealant on the base chip and sealing the at least one chip stack module. The at least one chip stack module may have an integral structure, in which a plurality of memory chips may be stacked and uniform. Each chip stack module of the at least one chip stack module may be on the base chip while having the integral structure.