A semiconductor chip is mounted on a mounting substrate. The semiconductor chip includes plural first bumps on a surface facing the mounting substrate. The plural first bumps each have a shape elongated in a first direction in plan view and are arranged in a second direction perpendicular to the first direction. The mounting substrate includes, on a surface on which the semiconductor chip is mounted, at least one first land connected to the plural first bumps. At least two first bumps of the plural first bumps are connected to each first land. The difference between the dimension of the first land in the second direction and the distance between the outer edges of two first bumps at respective ends of the arranged first bumps connected to the first land is 20 μm or less.

A method of fabricating a connection structure is disclosed. The method includes providing a substrate that has a top surface and includes a set of pads for soldering, each of which has a pad surface exposed from the top surface of the substrate. The method also includes applying a surface treatment to a part of the top surface of the substrate close to the pads and the pad surface of each pad so as to make at least the part of the top surface and the pad surfaces of the pads rougher. The surface treatment includes sandblasting.

Disclosed are examples of integrated circuit (IC) structures and techniques to fabricate IC structures. Each IC package may include a die (e.g., a flip-chip (FC) die) and one or more die interconnects to electrically couple the die to a substrate. The die interconnect may include a pillar, a wetting barrier on the pillar, and a solder cap on the wetting barrier. The wetting barrier may be wider than the pillar such that during solder reflow, solder wetting of sidewall of the pillar is minimized or prevented all together. The die interconnect may also include a low wetting layer formed on the wetting barrier, which can further mitigate solder wetting problems.

A semiconductor device includes a board having a solder resist layer with first and second openings on a first surface, and a first electrode on the first surface, a portion thereof exposed in the first opening and electrically connected to the board. A second electrode is located on the first surface having a portion exposed in the second opening and electrically connected to the board. A portion of the second electrode is covered by the solder resist layer. A first solder bump is on the first electrode and covers a side surface. A second solder bump is on the second electrode. A semiconductor chip has a first region and a second region facing the first surface. A third electrode is in the first region and electrically connected to the first solder bump. A fourth electrode is in the second region and electrically connected to the second solder bump.

A flip-chip mounting technique with high reliability is provided in flip-chip mounting using a Cu pillar. In a semiconductor device to be coupled to a mounting board via a Cu pillar, the Cu pillar is caused to have a laminated structure including a pillar layer, a barrier layer, and a bump in this order from below, and the bump is formed to be smaller than the barrier layer.

A semiconductor device according to the present disclosure includes a semiconductor substrate, a first electrode provided on the semiconductor substrate, an insulating layer including a first part provided on an upper surface of the first electrode, a second electrode including a main portion and an eaves portion, the main portion being provided on the upper surface of the first electrode, the eaves portion extending over the first part and solder covering an upper surface of the main portion and a part of an upper surface of the eaves portion wherein the insulating layer includes a second part covering a part of the upper surface of the eaves portion, the part being closer to an end portion of the eaves portion than the part covered by the solder and a third part connecting the first part and the second part and covering the end portion of the eaves portion.

Embodiments disclosed herein include electronic packages with fin pitch first level interconnects. In an embodiment, the electronic package comprises a die and a package substrate attached to the die by a plurality of first level interconnects (FLIs). In an embodiment, individual ones of the plurality of FLIs comprise, a first pad on the package substrate, a solder on the first pad, a second pad on the die, and a bump on the second pad. In an embodiment, the bump comprises a porous nanostructure, and the solder at least partially fills the porous nanostructure.

A preparation method of a backplane includes: forming an insulating structure layer having a groove on a base substrate by a mask exposure process, the groove being used for accommodating a metal trace; and repeating a metal sub-layer forming step including an ashing process and a wet etching process multiple times to form the metal trace positioned in the groove.

This application relates to semiconductor manufacturing, and more particularly to an interconnect structure for semiconductors with an ultra-fine pitch and a forming method thereof. The forming method includes: preparing copper nanoparticles using a vapor deposition device, where coupling parameters of the vapor deposition device are adjusted to control an initial particle size of the copper nanoparticles; depositing the copper nanoparticles on a substrate; invertedly placing a chip with copper pillars as I/O ports on the substrate; and subjecting the chip and the substrate to hot-pressing sintering to enable the bonding.

Microelectronic assemblies, and related devices and methods, are disclosed herein. For example, in some embodiments, a microelectronic assembly may include a package substrate including a dielectric material having a first surface and an opposing second surface, a first photodefinable material on at least a portion of the second surface, and a second photodefinable material on at least a portion of the first photodefinable material, wherein the second photodefinable material has a different material composition than the first photodefinable material.