Embodiments described herein provide techniques for forming a solder mask having a repeating pattern of features formed therein. The repeating pattern of features can be conceptually understood as a plurality of groove structures formed in the solder mask. The solder mask can be included in a semiconductor package that comprises the solder mask over a substrate and a molding compound over the solder mask that conforms to the repeating pattern of features. Several advantages are attributable to embodiments of the solder mask described herein. One advantage is that the repeating pattern of features formed in the solder mask increase the contact area between the solder mask and the molding compound. Increasing the contact area can assist with increasing adherence and conformance of the molding compound to the solder mask. This increased adherence and conformance assists with minimizing or eliminating interfacial delamination.

A chip part according to the present invention includes a substrate having a penetrating hole, a pair of electrodes formed on a front surface of the substrate and including one electrode overlapping the penetrating hole in a plan view and another electrode facing the one electrode, and an element formed on the front surface side of the substrate and electrically connected to the pair of electrodes.

A semiconductor device package and a method of manufacturing a semiconductor device package are provided. The semiconductor device package includes a carrier, a first component, a second component, and a protective element. The first component and the second component are arranged side by side in a first direction over the carrier. The protective element is disposed over a top surface of the carrier and extending from space under the first component toward a space under the second component. The protective element includes a first portion and a second portion protruded oppositely from edges of the first component by different distances, and the first portion and the second portion are arranged in a second direction angled with the first direction.

A semiconductor package includes: a package substrate; a semiconductor chip disposed on the package substrate; a transparent substrate disposed on the semiconductor chip; and an adhesive layer that is disposed between the semiconductor chip and the transparent substrate. The adhesive layer is configured to block light. The transparent substrate includes: a first lower side that faces the semiconductor chip, a second lower side that faces the semiconductor chip and that is disposed above the first lower side, and a first inner side wall that connects the first lower side and the second lower side, and the adhesive layer is in contact with the second lower side and the first inner side wall.

This document discloses techniques, apparatuses, and systems for a semiconductor device with a polymer layer. A semiconductor assembly is described that includes two semiconductor dies. The first semiconductor die has a first active side with first circuitry and a first back side opposite the first active side. Contact pads and a layer of polymer material are disposed at the first back side such that the layer of polymer material includes openings that expose the contact pads. The second semiconductor die has second circuitry disposed at a second active side. Interconnect structures are also disposed at the second active side such that the interconnect structures extend into the openings and couple to contact pads. A passivation layer (e.g., dielectric material) is disposed at the second active side and directly bonded to the layer of polymer material to reliably couple the two semiconductor dies.

A fan-out semiconductor package includes a wiring substrate including a first fan-in region, a fan-out region surrounding the first fan-in region, and a second fan-in region, a first fan-in chip structure, a second fan-in chip structure, a first redistribution structure including first redistribution elements disposed on a bottom surface of the wiring substrate, and a second redistribution structure disposed on a top surface of the wiring substrate, and a chip wiring structure formed on a top surface of the second chip, and the second redistribution structure includes a second redistribution layer extending to the first fan-in region and the fan-out region, a plurality of second redistribution vias integrally formed with the second redistribution layer and extending downward, and a seed layer surrounding the second redistribution layer and bottom surfaces of the plurality of second redistribution vias.

A warped semiconductor die is attached onto a substrate such as a leadframe by dispensing a first mass of die attach material onto an area of the substrate followed by dispensing a second mass of die attach material so that the second mass of die attach material provides a raised formation of die attach material. For instance, the second mass may be deposited centrally of the first mass. The semiconductor die is placed onto the first and second mass of die attach material with its concave/convex shape matching the distribution of the die attach material thus effectively countering undesired entrapment of air.

A semiconductor package includes a die stack including a first semiconductor die having a first interconnect structure, and a second semiconductor die having a second interconnect structure direct bonding to the first interconnect structure of the first semiconductor die. The second interconnect structure includes connecting pads disposed in a peripheral region around the first semiconductor die. First connecting elements are disposed on the connecting pads, respectively. A substrate includes second connecting elements on a mounting surface of the substrate. The first connecting elements are electrically connected to the second connecting elements through an anisotropic conductive structure.

A method for producing a semiconductor arrangement includes: forming a first metallization layer on a first side of a dielectric insulation layer, the first metallization layer having at least two sections, each section being separated from a neighboring section by a recess; arranging a semiconductor body on one of the sections of the first metallization layer; and forming at least one indentation between a first side of the semiconductor body and a closest edge of the respective section of the first metallization layer. A distance between the first side and the closest edge of the section of the first metallization layer is between 0.5 mm and 5 mm.

A chip part according to the present invention includes a substrate having a penetrating hole, a pair of electrodes formed on a front surface of the substrate and including one electrode overlapping the penetrating hole in a plan view and another electrode facing the one electrode, and an element formed on the front surface side of the substrate and electrically connected to the pair of electrodes.