A method for producing a 3D semiconductor device: providing a first level with a first single crystal layer; forming control circuitry of first transistors in and/or on the first level with a first metal layer above; forming a second metal layer above the first metal layer; forming a third metal layer above the second metal layer; forming at least one second level on top of or above the third metal layer; performing additional processing steps to form a plurality of second transistors within the second level; forming a fourth and fifth metal layers above second level; a global power distribution grid includes fifth metal, and local power distribution grid includes the second metal layer, where the fifth metal layer thickness is at least 50% greater than the second metal layer thickness.

A semiconductor device having a substrate, a semiconductor chip, and a plurality of electrode terminals is provided. The substrate has first and second principal surfaces. The semiconductor chip is disposed on the first principal surface. The electrode terminals are disposed on the second principal surface. The substrate has a via interconnection near a position at which an outer edge line of the semiconductor chip intersects an outer outline of the electrode terminal farthest from a center of the substrate, the electrode terminal farthest from the center of the substrate being among the plurality of electrode terminals overlapping the outer edge line in a predetermined condition as seen through the substrate of the semiconductor device from a direction perpendicular to the first principal surface, the via interconnection connecting a first interconnection layer on a first principal surface-side to a second interconnection layer on a second principal surface-side.

A semiconductor device includes: a thick copper member in which a semiconductor chip is mounted; a printed circuit board that is disposed on a front surface of the thick copper member and provided with an opening exposing a part of the front surface of the thick copper member, a wiring pattern, and conductive vias connecting the pattern and the thick copper member; a semiconductor chip mounted on the front surface of the thick copper member exposed through the opening and connected to the pattern by a metal wire; an electronic component mounted on a front surface of the printed circuit board opposite to a side facing the thick copper member and connected to the pattern; and a cap or an epoxy resin sealing the front surface of the printed circuit board opposite to a side facing the thick copper member, the chip, the component, and the metal wire.

A method of forming an assembly is provided. The method includes attaching a packaged semiconductor device to a substrate. An isolation structure is formed and located between the packaged semiconductor device and the substrate. An underfill material is dispensed between the packaged semiconductor device and the substrate. The isolation structure prevents the underfill material from contacting a first conductive connection formed between the packaged semiconductor device and the substrate.

A voltage-reference plane has gradient regions that provide altered thicknesses that are useful in a power-deliver network for a semiconductor package substrate. Different signal trace types are located over various portions of the gradient regions to facilitate signal integrity.

Disclosed is a flip-chip device. The flip-chip device includes a die having a plurality of under bump metallizations (UBMs); and a package substrate having a plurality of bond pads. The plurality of UBMs include a first set of UBMs having a first size and a first minimum pitch and a second set of UBMs having a second size and a second minimum pitch. The first set of UBMs and the second set of UBMs are each electrically coupled to the package substrate by a bond-on-pad connection.

A package substrate of a semiconductor package includes conductive lines of a first layer disposed on a first surface of a base layer and conductive lines of a second layer disposed on a second surface of the base layer. An opening hole located between a first remaining portion and a second remaining portion to separate the first and second remaining portions from each other. The first remaining portion is electrically connected to a first conductive line among the conductive lines of the second layer, and the second remaining portion is electrically connected to a second conductive line among the conductive lines of the second layer.

A semiconductor structure comprises a semiconductor substrate, a first trench capacitor, and a second trench capacitor. The substrate has first trenches arranged in a first arrangement direction with each first trench extending in a first extension direction and second trenches arranged in a second arrangement direction with each second trench extending in a second extension direction. The first trench capacitor includes first capacitor segments disposed inside the first trenches. The second trench capacitor includes second capacitor segments disposed inside the second trenches. One first capacitor segment of the first capacitor segments has an extending length different from that of another first capacitor segment of the first capacitor segments, and one second capacitor segment of the second capacitor segments has an extending length different from that of another second capacitor segment of the second capacitor segments.

An electronic component mounting package includes: an insulating base body including a principal face and a recess which opens in the principal face; and a metallic pattern including a plurality of metallic layers lying across a side face of the recess and the principal face. The metallic pattern includes, as an inner layer, at least one metallic layer selected from a tungsten layer, a nickel layer, and a gold layer, and an aluminum layer as an outermost layer. The metallic pattern includes an exposed portion corresponding to a part of the metallic layer constituting the inner layer which part is exposed at the principal face.

A substrate that includes a core layer comprising a first surface and a second surface, at least one first dielectric layer located over a first surface of the core layer, at least one second dielectric layer located over a second surface of the core layer, high-density interconnects located over a surface of the at least one second dielectric layer, interconnects located over the surface of the at least one second dielectric layer, and a solder resist layer located over the surface of the at least one second dielectric layer. A first portion of the solder resist layer that is touching the high-density interconnects includes a first thickness that is equal or less than a thickness of the high-density interconnects. A second portion of the solder resist layer that is touching the interconnects includes a second thickness that is greater than a thickness of the interconnects.