Disclosed herein are a light emitting device package, a backlight unit, an illumination apparatus, and a method of manufacturing a light emitting device package capable of being used for a display application or an illumination application. The light emitting device package includes: a flip-chip type light emitting device having a first terminal and a second terminal installed therebeneath; a substrate having a first electrode formed at one side of an electrode separating space and a second electrode formed at the other side thereof; a first conductive bonding member installed on the first electrode of the substrate so as to be electrically connected to the first terminal of the light emitting device; a second conductive bonding member installed on the second electrode of the substrate so as to be electrically connected to the second terminal of the light emitting device; a reflection encapsulant molded and installed on the substrate so as to form a reflection cup part reflecting light generated in the light emitting device and filled in the electrode separating space to form an electrode separating part; and a filler filled between the reflection cup part and the first and second conductive bonding members.

A semiconductor package comprises a leadframe, a component module, and a semiconductor die. The leadframe has a plurality of insertion terminals, a split die pad, and one or more leads. The component module has one or more passive components mounted on a substrate. The semiconductor die has an integrated circuit. The component module is mounted on a split die pad at a first surface of the leadframe and forms an electrical connection with the insertion terminals. Further, the semiconductor die is mounted on the split die pad at a second surface of the leadframe which is opposite to the first surface.

A packaging substrate is provided, which includes: an insulating layer; a plurality of conductive bumps formed on the insulating layer, wherein each of the conductive bumps has a post body exposed from the insulating layer and a conductive pad embedded in the insulating layer, the post body being integrally formed with and less in width than the conductive pad; and a plurality of conductive posts disposed on the conductive pads and embedded in the insulating layer. As such, a semiconductor chip can be bonded to the packaging substrate through the conductive bumps. The present disclosure further provides a method for fabricating the packaging substrate.

A jointed body that has been solid-phase jointed at normal temperature and that has a non-conventional structure is presented. The jointed body is formed by solid-phase joining a first jointed member to a second jointed member, and has a junction interface between the first member and the second member. This jointed body includes an average crystal grain size in a near interface structure that constitutes a near interface area having a total width of 20 micrometers and extending at both sides of the junction interface as a center is 75-100% of an average crystal grain size in an around interface structure that constitutes around interface areas located at both outer sides of the near interface area. In the jointed body, the near interface structure after the joining is almost the same as the structure before the joining, allowing the jointed body to exert similar characteristics to the jointed members.

Disclosed herein are channeled lids for integrated circuit (IC) packages, as well as related methods and devices. For example, in some embodiments, an IC package may include a die between a lid and a package substrate. A bottom surface of the lid may include a channel that at least partially overlaps the die.

A semiconductor device including a substrate, a semiconductor package, a thermal conductive bonding layer, and a lid is provided. The semiconductor package is disposed on the substrate. The thermal conductive bonding layer is disposed on the semiconductor package. The lid is attached to the thermal conductive bonding layer and covers the semiconductor package to prevent coolant from contacting the semiconductor package.

Provided are a wafer level package and a method of manufacturing the same, wherein an underfill sufficiently fills a space between a redistribution substrate and a semiconductor chip, thereby reducing warpage. The wafer level package includes a redistribution substrate including at least one redistribution layer (RDL), a semiconductor chip on the redistribution substrate, and an underfill filling a space between the redistribution substrate and the semiconductor chip. The underfill covers side surfaces of the semiconductor chip. The redistribution substrate includes a trench having a line shape and extending in a first direction along a first side surface of the semiconductor chip.

A chip arranging method for arranging a plurality of chips on a wafer includes a groove forming step of forming a plurality of intersecting grooves that mark off each of chip placement regions on the front surface side of the wafer, a liquid supplying step of supplying a liquid to the chip placement regions, a chip placing step of placing the chips on the liquid to position the chips in the chip placement regions by the surface tension of the liquid after carrying out the liquid supplying step, and a liquid removing step of removing the liquid to arrange the plurality of chips on the wafer after carrying out the chip placing step.

A conductive structure is provided. The conductive structure includes a first conductive layer, a second conductive layer, and an insulating layer sandwiched between the first conductive layer and second conductive layer. The insulating layer has a first opening and a second opening through which the first conductive layer is electrically connected to the second conductive layer. The partition between the first opening and the second opening has a width greater than 0 and less than or equal to the average width of the first opening and second opening.

A method of assembling a flip chip on a leadframe package. A locking dual leadframe (LDLF) includes a top metal frame portion including protruding features and a die pad and a bottom metal frame portion having apertures positioned lateral to the die pad. The protruding features and apertures are similarly sized and alignable. A flipped integrated circuit (IC) die having a bottomside and a topside including circuitry connected to bond pads having solder balls on the bond pads is mounted with its topside onto the top metal frame portion. The top metal frame portion is aligned to the bottom metal frame portion so that the protruding features are aligned to the apertures. The bottomside of the IC die is pressed with respect to a top surface of the bottom frame portion, wherein the protruding features penetrate into the apertures.