An electrical connection includes a first driving substrate, a first adhesive layer, a first bonding pad a first bonding pad and a second bonding pad. The first driving substrate includes a first substrate and a first dielectric layer on the first substrate. The first adhesive layer is at a sidewall of the first dielectric layer of the first driving substrate. The first bonding pad is on the first substrate of the first driving substrate and in contact with the first adhesive layer, and the first bonding pad includes a plurality of grains, the grains are connected with each other, the grains include [111]-oriented copper grains, and a maximum width of the first bonding pad is equal to or less than 8 microns. The second bonding pad is on the first bonding pad.

Methods and apparatus for solder connections. An apparatus includes a substrate having a conductive terminal on a surface; a passivation layer overlying the surface of the substrate and the conductive terminal; an opening in the passivation layer exposing a portion of the conductive terminal; at least one stud bump bonded to the conductive terminal in the opening and extending in a direction normal to the surface of the substrate; and a solder connection formed on the conductive terminal in the opening and enclosing the at least one stud bump. Methods for forming the solder connections are disclosed.

A customized seal ring for a semiconductor device is formed of multiple seal ring cells that are selected and arranged to produce a seal ring design. The cells include first cells that are coupled to ground and second cells that are not coupled to ground. The second cells that are not coupled to ground, include a higher density of metal features in an inner portion thereof, than the first seal ring cells. Dummy metal vias and other metal features that may be present in the inner portion of the second seal ring cells are absent from the inner portion of the first seal ring cells that are coupled to ground. The seal ring design may include various arrangements, including alternating and repeating sequences of the different seal ring cells.

A semiconductor device includes a semiconductor element, a lead on which the semiconductor element is mounted, a bonding member fixing the semiconductor element to the lead, and a resin package enclosing the semiconductor element and a portion of the lead. This lead is formed with a groove recessed at a location spaced from the semiconductor element. The groove has first and second inner surfaces, where the first inner surface is closer to the semiconductor element than is the second inner surface. The angle the first inner surface forms with respect to the thickness direction of the semiconductor element is smaller than the angle the second inner surface forms with respect to the thickness direction.

A customized seal ring for a semiconductor device is formed of multiple seal ring cells that are selected and arranged to produce a seal ring design. The cells include first cells that are coupled to ground and second cells that are not coupled to ground. The second cells that are not coupled to ground, include a higher density of metal features in an inner portion thereof, than the first seal ring cells. Dummy metal vias and other metal features that may be present in the inner portion of the second seal ring cells are absent from the inner portion of the first seal ring cells that are coupled to ground. The seal ring design may include various arrangements, including alternating and repeating sequences of the different seal ring cells.

An electrical connection includes a first driving substrate, a first adhesive layer, a first bonding pad a first bonding pad and a second bonding pad. The first driving substrate includes a first substrate and a first dielectric layer on the first substrate. The first adhesive layer is at a sidewall of the first dielectric layer of the first driving substrate. The first bonding pad is on the first substrate of the first driving substrate and in contact with the first adhesive layer, and the first bonding pad includes a plurality of grains, the grains are connected with each other, the grains include [111]-oriented copper grains, and a maximum width of the first bonding pad is equal to or less than 8 microns. The second bonding pad is on the first bonding pad.

The invention provides a semiconductor package. The semiconductor package includes a semiconductor die having a central area and a peripheral area surrounding the central area. A first conductive bump is disposed on the semiconductor die in the central area. A second conductive bump is disposed on the semiconductor die in the peripheral area. An area ratio of the first conductive bump to the second conductive bump from a top view is larger than 1, and less than or equal to 3.

A semiconductor device includes a semiconductor element, a lead on which the semiconductor element is mounted, a bonding member fixing the semiconductor element to the lead, and a resin package enclosing the semiconductor element and a portion of the lead. This lead is formed with a groove recessed at a location spaced from the semiconductor element. The groove has first and second inner surfaces, where the first inner surface is closer to the semiconductor element than is the second inner surface. The angle the first inner surface forms with respect to the thickness direction of the semiconductor element is smaller than the angle the second inner surface forms with respect to the thickness direction.

A semiconductor device has a semiconductor die and first insulating layer formed over the semiconductor die. A plurality of first micro-vias can be formed in the first insulating layer. A conductive layer is formed in the first micro-openings and over the first insulating layer. A second insulating layer is formed over the first insulating layer and conductive layer. A portion of the second insulating layer is removed to expose the conductive layer and form a plurality of second micro-openings in the second insulating layer over the conductive layer. The second micro-openings can be micro-vias, micro-via ring, or micro-via slots. Removing the portion of the second insulating layer leaves an island of the second insulating layer over the conductive layer. A bump is formed over the conductive layer. A third insulating layer is formed in the second micro-openings over the bump. The second micro-openings provide stress relief.

Methods and apparatus for solder connections. An apparatus includes a substrate having a conductive terminal on a surface; a passivation layer overlying the surface of the substrate and the conductive terminal; an opening in the passivation layer exposing a portion of the conductive terminal; at least one stud bump bonded to the conductive terminal in the opening and extending in a direction normal to the surface of the substrate; and a solder connection formed on the conductive terminal in the opening and enclosing the at least one stud bump. Methods for forming the solder connections are disclosed.