An integrated circuit device includes a support substrate, a first semiconductor chip and a second semiconductor chip provided on the support substrate, and a connection member made of solder. The first semiconductor chip and the second semiconductor chip each includes a semiconductor substrate, an interconnect layer provided on the semiconductor substrate, and a pad provided on a side surface of the interconnect layer. The connection member contacts a side surface of the pad of the first semiconductor chip and a side surface of the pad of the second semiconductor chip.

An integrated circuit device includes a support substrate, a first semiconductor chip and a second semiconductor chip provided on the support substrate, and a connection member made of solder. The first semiconductor chip and the second semiconductor chip each includes a semiconductor substrate, an interconnect layer provided on the semiconductor substrate, and a pad provided on a side surface of the interconnect layer. The connection member contacts a side surface of the pad of the first semiconductor chip and a side surface of the pad of the second semiconductor chip.

Embodiments relate to the design of a device capable of increasing the electrical performance of an interconnect feature by amplifying the current carrying capacity of an interconnect feature. The device comprises a first body comprising a first surface with at least one nanoporous conductive structure protruding from the first surface. The device further comprises a second body comprising a second surface with arrays of nanofibers extending from the second surface and penetrating into corresponding nanoporous conductive structures to form conductive pathways between the first body and the second body.

Embodiments relate to the design of a device capable of increasing the electrical performance of an interconnect feature by amplifying the current carrying capacity of an interconnect feature. The device comprises a first body comprising a first surface with at least one nanoporous conductive structure protruding from the first surface. The device further comprises a second body comprising a second surface with arrays of nanofibers extending from the second surface and penetrating into corresponding nanoporous conductive structures to form conductive pathways between the first body and the second body.

Methods for forming semiconductor die assemblies with heat transfer features are disclosed herein. In some embodiments, the methods comprise providing a wafer having a first side and a second side opposite the first side, attaching a semiconductor die stack to the first side of the wafer, and forming a plurality of heat transfer features at the second side of the wafer. The heat transfer features can be defined by a plurality of grooves that define an exposed continuous surface of the wafer at the second side compared to a planar surface of the wafer.

Methods for forming semiconductor die assemblies with heat transfer features are disclosed herein. In some embodiments, the methods comprise providing a wafer having a first side and a second side opposite the first side, attaching a semiconductor die stack to the first side of the wafer, and forming a plurality of heat transfer features at the second side of the wafer. The heat transfer features can be defined by a plurality of grooves that define an exposed continuous surface of the wafer at the second side compared to a planar surface of the wafer.

Capacitive interconnects and processes for fabricating the capacitive interconnects are provided. In some embodiments, the capacitive interconnect includes first metal layers, second metal layers; and dielectric layers including a dielectric layer that intercalates a first metal layer of the first metal layers and a second metal layer of the second metal layers. Such layers can be assembled in a nearly concentric arrangement, where the dielectric layer abuts the first metal layer and the second metal layer abuts the dielectric layer. In addition, the capacitive interconnect can include a first electrode electrically coupled to at least one of the first metal layers, and a second electrode electrically coupled to at least one of the second metal layers, the second electrode assembled opposite to the first electrode. The first electrode and the second electrode can include respective solder tops.

Semiconductor package structures are provided. An interposer is bonded to a printed circuit board (PCB) or package substrate through first solder bumps disposed on a first side of the interposer. The first solder bumps have a first pitch. A plurality of semiconductor chips are formed, and each of the semiconductor chips is bonded to a second side of the interposer through second solder bumps. The second solder bumps have a second pitch that is less than the first pitch. Each of the semiconductor chips includes a substrate with one or more transistors or integrated circuits formed thereon.

Embodiments relate to forming nanoporous contacts on a receiving substrate without using a seed layer on the receiving substrate. The nanoporous contacts can be used to create bonds between electronic components and the receiving substrate. To form the contacts, a photoresist mask is created on the receiving substrate by a photolithographic process. Through a sputtering process, portions of co-alloy on a depositing substrate are transferred to the receiving substrate with the photoresist mask. The photoresist mask is removed from the receiving substrate. The remaining co-alloy portions on the receiving substrate undergo a de-alloying process to form an array of nanoporous contacts.

There is provided a bonding wire for a semiconductor device including a coating layer having Pd as a main component on a surface of a Cu alloy core material and a skin alloy layer containing Au and Pd on a surface of the coating layer, the bonding wire further improving 2nd bondability on a Pd-plated lead frame and achieving excellent ball bondability even in a high-humidity heating condition. The bonding wire for a semiconductor device including the coating layer having Pd as a main component on the surface of the Cu alloy core material and the skin alloy layer containing Au and Pd on the surface of the coating layer has a Cu concentration of 1 to 10 at % at an outermost surface thereof and has the core material containing either or both of Pd and Pt in a total amount of 0.1 to 3.0% by mass, thereby achieving improvement in the 2nd bondability and excellent ball bondability in the high-humidity heating condition. Furthermore, a maximum concentration of Au in the skin alloy layer is preferably 15 at % to 75 at %.