A semiconductor package includes a connection structure including an insulating layer, a redistribution layer disposed on the insulating layer, and a connection via penetrating through the insulating layer and connected to the redistribution layer, a semiconductor chip having an active surface on which connection pads are disposed and an inactive surface opposing the active surface, and having the active surface disposed on the connection structure to face the connection structure, and an encapsulant covering at least a portion of the semiconductor chip, wherein the semiconductor chip includes a groove formed in the active surface, and the groove has a shape in which a width of a region of at least a portion of an internal region located closer to a central portion of the semiconductor chip than the active surface is greater than a width of an entrance region.

A mixed-orientation multi-die (“MOMD”) integrated circuit package includes dies mounted in different physical orientations. An MOMD package includes both (a) one or more dies horizontally-mounted dies (HMDs) mounted horizontally to a horizontally-extending die mount base and (b) one or more vertically-mounted dies (VMDs) mounted vertically to the horizontally-extending die mount base. HMDs may include FPGAs or other high performance chips, while VMDs may include low performance chips and other physical structures such as heat dissipators, memory, high voltage/analog devices, sensors, or MEMS, for example. The die mount base of an MOMD package may include structures for aligning and mounting VMD(s), for example, VMD slots for receiving each mounted VMD, and VMD alignment structures that facilitate aligning and/or guiding a vertical mounting of each VMD to the die mount base. MOMD packages may provide a reduced lateral footprint and increased die integration per unit area, as compared with conventional multi-die packages.

A method of forming a semiconductor structure includes forming first semiconductor devices over a first substrate, forming a first dielectric material layer over the first semiconductor devices, forming vertical recesses in the first dielectric material layer, such that each of the vertical recesses vertically extends from a topmost surface of the first dielectric material layer toward the first substrate, forming silicon nitride material portions in each of the vertical recesses; and locally irradiating a second subset of the silicon nitride material portions with a laser beam. A first subset of the silicon nitride material portions that is not irradiated with the laser beam includes first silicon nitride material portions that apply tensile stress to respective surrounding material portions, and the second subset of the silicon nitride material portions that is irradiated with the laser beam includes second silicon nitride material portions that apply compressive stress to respective surrounding material portions.

Implementations of a method of forming semiconductor packages may include: providing a wafer having a plurality of devices, etching one or more trenches on a first side of the wafer between each of the plurality of devices, applying a molding compound to the first side of the wafer to fill the one or more trenches; grinding a second side of the wafer to a desired thickness, and exposing the molding compound included in the one or more trenches. The method may include etching the second side of the wafer to expose a height of the molding compound forming one or more steps extending from the wafer, applying a back metallization to a second side of the wafer, and singulating the wafer at the one or more steps to form a plurality of semiconductor packages. The one or more steps may extend from a base of the back metallization.

Representative implementations of techniques and devices are used to reduce or prevent conductive material diffusion into insulating or dielectric material of bonded substrates. Misaligned conductive structures can come into direct contact with a dielectric portion of the substrates due to overlap, especially while employing direct bonding techniques. A barrier interface that can inhibit the diffusion is disposed generally between the conductive material and the dielectric at the overlap.

A semiconductor package according to an aspect includes a package substrate, a first semiconductor chip disposed on the package substrate and including a first through electrode, a second semiconductor chip stacked on the first semiconductor chip and having a second through electrode, and a nonconductive film disposed in a bonding zone between the first semiconductor chip and the second semiconductor chip. At an edge portion of the bonding zone, an edge portion of the first semiconductor chip is recessed in the lateral direction, based on an edge portion of the second semiconductor chip.

A bonded structure is disclosed. The bonded structure includes a first element and a second element that is bonded to the first element along a bonding interface. The bonding interface has an elongate conductive interface feature and a nonconductive interface feature. The bonded structure also includes an integrated device that is coupled to or formed with the first element or the second element. The elongate conductive interface feature has a recess through a portion of a thickness of the elongate conductive interface feature. A portion of the nonconductive interface feature is disposed in the recess.

Techniques are disclosed for forming a frame on the backplane comprising structures at least partially circumscribing or enclosing metal contacts on the backplane. In some embodiments, the frame may comprise a photoresist. The dimensions and structural integrity of the frame can help prevent misalignment and/or damage of physical obtrusions of light-emitting structures during a bonding process of the light-emitting structures to the backplane.

A hetero-integrated structure includes a substrate, a die, a passivation layer, a first redistribution layer, a second redistribution layer, and connecting portions. The die is attached on the substrate. The die has an active surface and a non-active surface. The active surface has pads. The passivation layer covers sidewalls and a surface of the die to expose a surface of the pads. The first redistribution layer is located on the passivation layer and electrically connected to the pads. The second redistribution layer is located on the substrate and adjacent to the die. The connecting portions are connected to the first redistribution layer and the second redistribution layer.

A semiconductor device includes an N-type semiconductor substrate comprising silicon, an N-type low-concentration impurity layer that is in contact with the upper surface of the N-type semiconductor substrate, a metal layer that is in contact with the entire lower surface of the N-type semiconductor substrate and has a thickness of at least 20 m, and first and second vertical MOS transistors formed in the low-concentration impurity layer. The ratio of the thickness of the metal layer to the thickness of a semiconductor layer containing the N-type semiconductor substrate and the low-concentration impurity layer is greater than 0.27. The semiconductor device further includes a support comprising a ceramic material and bonded to the entire lower surface of the metal layer only via a bonding layer.