An electronic package is provided. An electronic component and a plurality of conductive pillars electrically connected with the electronic component are embedded in an encapsulating layer. Each of the conductive pillars has a circumferential surface and two end surfaces wider than the circumferential surface in width. The encapsulating layer encapsulates and protects the electronic component effectively, so as to improve the reliability of the electronic package. A method for fabricating the electronic package is also provided.

A structure for a semiconductor device includes a copper (Cu) layer and a first nickel (Ni) alloy layer with a Ni grain size a.sub.1. The structure also includes a second Ni alloy layer with a Ni grain size a.sub.2, wherein a.sub.1<a.sub.2. The first Ni alloy layer is between the Cu layer and the second Ni alloy layer. The structure further includes a tin (Sn) layer. The second Ni alloy layer is between the first Ni alloy layer and the Sn layer.

A pillar-type connection includes a first conductive layer that includes a hollow core. A second conductive layer is connected to the first conductive layer defining a conductive pillar that includes a top surface defining a recess aligned with the hollow core.

An electronic package is provided. An electronic component and a plurality of conductive pillars electrically connected with the electronic component are embedded in an encapsulating layer. Each of the conductive pillars has a circumferential surface and two end surfaces wider than the circumferential surface in width. The encapsulating layer encapsulates and protects the electronic component effectively, so as to improve the reliability of the electronic package. A method for fabricating the electronic package is also provided.

Disclosed are interconnects in which one substrate having a high melting temperature, lead-free solder column is joined to a second substrate having openings filled with a low melting temperature, lead-free solder such that the high melting temperature, lead-free solder column penetrates into the low melting temperature, lead-free solder so as to obtain a short moment arm of solder.

A finned contact of an IC device may be utilized to electrically connect the IC device to external circuitry. The finned contact may be fabricated by forming a base upon the IC device and subsequently forming two or more fins upon the base. Each fin may be formed of the same and/or different material(s) as the base. Each fin may include layer(s) of one or materials. The fins may be located upon the base inset from the sidewall(s) of the base. The fins may be arranged as separated ring portions that are concentric with the base. The fins may drive current into the external circuitry connected thereto. Solder may be drawn towards the center of the base within an inner void that is internal to the fins, thereby limiting the likelihood of solder bridging with a neighboring contact.

In an embodiment, a method includes: stacking a plurality of first dies to form a device stack; revealing testing pads of a topmost die of the device stack; testing the device stack using the testing pads of the topmost die; and after testing the device stack, forming bonding pads in the topmost die, the bonding pads being different from the testing pads.

The present disclosure provides a semiconductor structure and a method of manufacturing the semiconductor structure. The semiconductor structure includes a substrate, a plurality of metallic pillars, a plurality of metallic protrusions, a capping layer, and a passivation layer. The metallic pillars are disposed on the substrate. The metallic protrusions extend from an upper surface of the metallic pillars. The capping layer is disposed on the metallic protrusions. The passivation layer is disposed on sidewalls of the protrusions and the capping layer.

A finned contact of an IC device may be utilized to electrically connect the IC device to external circuitry. The finned contact may be fabricated by forming a base upon the IC device and subsequently forming two or more fins upon the base. Each fin may be formed of the same and/or different material(s) as the base. Each fin may include layer(s) of one or materials. The fins may be located upon the base inset from the sidewall(s) of the base. The fins may be arranged as separated ring portions that are concentric with the base. The fins may drive current into the external circuitry connected thereto. Solder may be drawn towards the center of the base within an inner void that is internal to the fins, thereby limiting the likelihood of solder bridging with a neighboring contact.

A microelectronic device has a bump bond structure including an electrically conductive pillar with an expanded head, and solder on the expanded head. The electrically conductive pillar includes a column extending from an I/O pad to the expanded head. The expanded head extends laterally past the column on at least one side of the electrically conductive pillar. In one aspect, the expanded head may have a rounded side profile with a radius approximately equal to a thickness of the expanded head, and a flat top surface. In another aspect, the expanded head may extend past the column by different lateral distances in different lateral directions. In a further aspect, the expanded head may have two connection areas for making electrical connections to two separate nodes. Methods for forming the microelectronic device are disclosed.