A semiconductor package includes a first substrate having a first surface and including a first electrode, a first bump pad located on the first surface of the first substrate and connected to the first electrode, a second substrate having a second surface facing the first surface of the first substrate and including a second electrode, a second bump pad and neighboring second bump pads on the second surface of the second substrate, and a bump structure. The second bump pad has a recess structure. That is recessed from a side surface of the second bump pad toward a center thereof. The second bump pad may be connected to the second electrode. A bump structure may contact the first bump pad and the second bump pad. The bump structure may have a portion protruding through the recess structure. The neighboring second bump pads may neighbor the second bump pad and include recess structures oriented in different directions.

A semiconductor device package includes a first conductive structure, a stress buffering layer and a second conductive structure. The first conductive structure includes a substrate, at least one first electronic component embedded in the substrate, and a first circuit layer disposed on the substrate and electrically connected to the first electronic component. The first circuit layer includes a conductive wiring pattern. The stress buffering layer is disposed on the substrate. The conductive wiring pattern of the first circuit layer extends through the stress buffering layer. The second conductive structure is disposed on the stress buffering layer and the first circuit layer.

A substrate is capable of effectively reinforcing a connecting portion between an electronic component and the substrate. The substrate is a substrate on which a first electronic component having a plurality of bumps is to be mounted, and includes a base portion including an insulator and having, on the upper face thereof, at least one groove portion configured to store a tip portion of at least one of the bumps, and includes an electrode formed on at least the bottom face of the groove portion.

A device for mounting a semiconductor element includes a metal plate serving as a base, a roughened silver plating layer with acicular projections, formed on at least either of: (a) top faces; and (b) faces that form concavities or through holes between the top faces and bottom faces; of the metal plate, and a reinforcing plating layer covering, as an outermost plating layer, an outer surface of the acicular projections in the roughened silver plating layer. The roughened silver plating layer has a crystal structure in which the crystal direction <101> occupies a largest proportion among the crystal directions <001>, <111>, and <101>. An outer surface of the reinforcing plating layer is shaped to have acicular projections with a surface area ratio of 1.30 or more and 6.00 or less to the corresponding smooth surface, as inheriting the shape of the acicular projections in the roughened silver plating layer.

Even in a case where a pad becomes smaller, solder connection strength is improved. A semiconductor device includes a pad, a diffusion layer, and a melting layer. The pad included by the semiconductor device includes a concave portion on a surface at which solder connection is to be performed. The diffusion layer included by the semiconductor device is disposed at the concave portion and constituted with a metal which remains on the surface of the pad while diffusing into solder upon the solder connection. The melting layer included by the semiconductor device is disposed adjacent to the diffusion layer and constituted with a metal which diffuses and melts into the solder upon the solder connection.

A method for electrically coupling a pad and a front face of a pillar, including shaping the front face pillar, the front face having at least partially a convex surface, applying a suspension to the front face or to the pad, wherein the suspension includes a carrier fluid, electrically conducting microparticles and electrically conducting nanoparticles, arranging the front face of the pillar opposite to the pad at a distance such that the carrier fluid bridges at least partially a gap between the front face of the pillar and the pad, evaporating the carrier fluid thereby confining the microparticles and the nanoparticles, and thereby arranging the nanoparticles and the microparticles as percolation paths between the front face of the pillar and the pad, and sintering the arranged nanoparticles for forming metallic bonds at least between the nanoparticles and/or between the nanoparticles and the front face of the pillar or the pad.

Implementations of a semiconductor package may include: a first wafer having a first surface and a first set of blade interconnects, the first set of blade interconnects extending from the first surface. The package may include a second wafer having a first surface and a second set of blade interconnects, the second set of blade interconnects extending from the first surface and oriented substantially perpendicularly to a direction of orientation of the first set of blade interconnects. The first set of blade interconnects may be hybrid bonded to the second set of blade interconnects at a plurality of points of intersection between the first and second set of blade interconnects. The plurality of points of intersection may be located along a length of each blade interconnect of the first set of blade interconnects, and along the length of each blade interconnect of the second set of blade interconnects.

The present disclosure relates to a semiconductor structure. The semiconductor structure includes a semiconductor unit, one or more bonding structures, and at least one supporter. The semiconductor unit includes at least one via. The one or more bonding structures are disposed over the semiconductor unit and electrically connected to the at least one via. The at least one supporter is disposed over the semiconductor unit. The at least one supporter is a metal block or a polymer block spaced apart from the one or more bonding structures.

A stackable via package includes a substrate having an upper surface and a trace on the upper surface, the trace including a terminal. A solder ball is on the terminal. The solder ball has a solder ball diameter A and a solder ball height D. A via aperture is formed in a package body enclosing the solder ball to expose the solder ball. The via aperture includes a via bottom having a via bottom diameter B and a via bottom height C from the upper surface of the substrate, where A<B and 0=<C<D. The shape of the via aperture prevents solder deformation of the solder column formed from the solder ball as well as prevents solder bridging between adjacent solder columns.

In some examples, an electronic device comprises a first component having a surface, a second component having a surface, and a bond layer positioned between the surfaces of the first and second components to couple the first and second components to each other. The bond layer includes a set of metallic nanowires and a dielectric portion. The dielectric portion comprises a polymer matrix and dielectric nanoparticles.