A device includes a semiconductor chip including an electrical contact arranged on a main surface of the semiconductor chip. The device includes an external connection element configured to provide a first coax-like electrical connection between the device and a printed circuit board, wherein the first coax-like electrical connection includes a section extending in a direction vertical to the main surface of the semiconductor chip. The device further includes an electrical redistribution layer arranged over the main surface of the semiconductor chip and configured to provide a second coax-like electrical connection between the electrical contact of the semiconductor chip and the external connection element, wherein the second coax-like electrical connection includes a section extending in a direction parallel to the main surface of the semiconductor chip.

A fan-out semiconductor package includes: a first connection member having a through-hole; a semiconductor chip disposed in the through-hole of the first connection member and having an active surface having connection pads disposed thereon and an inactive surface opposing the active surface; an encapsulant encapsulating at least portions of the first connection member and the inactive surface of the semiconductor chip; a pattern layer disposed on the encapsulant and covering at least portions of the encapsulant adjacent to the inactive surface of the semiconductor chip; vias penetrating through the encapsulant and connecting the pattern layer and the inactive surface of the semiconductor chip to each other; and a second connection member disposed on the first connection member and the active surface of the semiconductor chip and including a redistribution layer electrically connected to the connection pads of the semiconductor chip.

Apparatuses and methods using a silicon on insulator (SOI) substrate are described. An example apparatus includes: a substrate including a first surface and a second surface opposite to the first surface; a circuit formed in the first surface; a first electrode through the substrate from the first surface to the second surface; and a first insulative film around the first electrode. The first electrode includes: a first portion formed in the substrate; and a second portion continuous to the first portion and protruding from the second surface. The first insulative film is formed between the first portion of the first electrode in the substrate and extending to a side surface of the second portion of the first electrode.

A method is provided for producing at least one electrical via in a substrate, the method comprising: producing a protective layer over a component structure which has been produced or is present on a front side of the substrate; forming at least one contact hole which extends from a surface of a backside of the substrate to a contact surface of the component structure; forming a metal-containing and thus conductive lining in the at least one contact hole creating a hollow electrically conductive structure in the at least one contact hole; and applying a passivation layer over the backside of the substrate, the passivation layer spanning over the hollow electrically conductive structure for forming the at least one electrical via. Also provided is a micro-technical component comprising at least one electrical via.

Introducing an underfill material over contact pads on a surface of an integrated circuit substrate; and ablating the introduced underfill material to expose an area of the contact pads using temporally coherent electromagnetic radiation. A method including first ablating an underfill material to expose an area of contact pads on a substrate using temporally coherent electromagnetic radiation; introducing a solder to the exposed area of the contact pads; and second ablating the underfill material using temporally coherent electromagnetic radiation. A method including introducing an underfill material over contact pads on a surface of an integrated circuit substrate; defining an opening in the underfill material to expose an area of the contact pads using temporally coherent electromagnetic radiation; introducing a solder material to the exposed area of the contact pads; and after introducing the solder, removing the sacrificial material.

An electronics package includes a thermal lid over a flip chip component such that the thermal lid is in contact with a surface of a flip chip component and one or more thermal vias in a substrate on which the flip chip component is mounted. The thermal lid dissipates heat from the flip chip component by way of the thermal vias to improve the thermal performance of the electronics package.

To improve reliability of a semiconductor device, in a method of manufacturing the semiconductor device, a semiconductor substrate having an insulating film in which an opening that exposes each of a plurality of electrode pads is formed is provided, and a flux member including conductive particles is arranged over each of the electrode pads. Thereafter, a solder ball is arranged over each of the electrode pads via the flux member, and is then heated via the flux member so that the solder ball is bonded to each of the electrode pads. The width of the opening of the insulating film is smaller than the width (diameter) of the solder ball.

Power gate placement techniques in three-dimensional (3D) integrated circuits (ICs) (3DICs) are disclosed. Exemplary aspects of the present disclosure contemplate consolidating power gating circuits or cells into a single tier within a 3DIC. Still further, the power gating circuits are consolidated in a tier closest to a voltage source. This closest tier may include a backside metal layer that allows a distance between the voltage source and the power gating circuits to be minimized. By minimizing the distance between the voltage source and the power gating circuits, power loss from routing elements therebetween is minimized. Further, by consolidating the power gating circuits in a single tier, routing distances between the power gating circuits and downstream elements may be minimized and power loss from those routing elements are minimized. Other advantages are likewise realized by placement of the power gating circuits according to exemplary aspects of the present disclosure.

A multi-layer pillar and method of fabricating the same is provided. The multi-layer pillar is used as an interconnect between a chip and substrate. The pillar has at least one low strength, high ductility deformation region configured to absorb force imposed during chip assembly and thermal excursions.

An electronic part includes a substrate, an insulating film formed over the substrate, a first pillar electrode, a first solder formed over the first pillar electrode, a second pillar electrode, and a second solder formed over the second pillar electrode. The first pillar electrode over which the first solder is formed is formed over a first region of an insulating film including a level difference between a first opening portion and a peripheral portion of the first opening portion. The second pillar electrode over which the second solder is formed is formed over a second region of the insulating film including a second opening portion whose opening area is larger than that of the first opening portion. For example, the second pillar electrode over which the second solder is formed is formed over the second opening portion of the insulating film.