A method of dispensing an underfill material on a semiconductor device package. A substrate having a semiconductor chip electrically connected thereto and offset from the substrate by solder joints is provided. The semiconductor chip has a footprint defined by a length and width of the semiconductor chip. Standoff heights between the substrate and the semiconductor chip are calculated and used to determine a volume of underfill material needed to substantially fill a space between the substrate and the semiconductor chip. The determined volume of underfill material is dispensed on the substrate such that the space between the substrate and the semiconductor chip is substantially filled by the underfill material. The method may allow for improved dispensing an underfill material to substantially fill the space between the substrate and semiconductor chip when variations in standoff height are present.

A semiconductor device package includes a substrate, and interconnection structure and a package body. The interconnection structure is disposed on the substrate. The interconnection structure has a conductive structure and a first dielectric layer covering a portion of the conductive structure. The conductive structure defines an antenna feeding point. The package body is disposed on the substrate and covers the interconnection structure.

An electronic device package and method of fabricating such a package includes a first and second components encapsulated in a volume of molding material. A surface of the first component is bonded to a surface of the second component. Upper and lower sets of redistribution lowers that include, respectively, first and second sets of conductive interconnects are formed on opposite sides of the molding material. A through-package interconnect passes through the volume of molding material and has ends that terminate, respectively, within the upper set of redistribution layers and within the lower set of redistribution layers.

A die includes a substrate, a conductive pad, a connector a protection layer, and a passivation layer. The conductive pad is disposed over the substrate. The connector is disposed on the conductive pad. The connector comprises a seed layer and a conductive post on the seed layer. The protection layer laterally covers the connector. The passivation layer is disposed between the protection layer and the conductive pad. The conductive post is separated from the passivation layer and the protection layer by the seed layer.

A circuit device includes: a first substrate having a first barrier layer; a second substrate having a second barrier layer; a first conductive portion arranged over the first barrier layer; a second conductive portion arranged over the second barrier layer; a first expanding pad arranged on the first conductive portion and including a first contact area greater than that of the first conductive portion; and a second expanding pad bonded to the first expanding pad, arranged on the second conductive portion and including a second expanded contact area greater than that of the second conductive portion. The first barrier layer and the second barrier layer include aluminum fluoride.

The present disclosure provides a packaging method, including: providing a first semiconductor substrate; forming a bonding region on the first semiconductor substrate, wherein the bonding region of the first semiconductor substrate includes a first bonding metal layer and a second bonding metal layer; providing a second semiconductor substrate having a bonding region, wherein the bonding region of the second semiconductor substrate includes a third bonding layer; and bonding the first semiconductor substrate to the second semiconductor substrate by bringing the bonding region of the first semiconductor substrate in contact with the bonding region of the second semiconductor substrate; wherein the first and third bonding metal layers include copper (Cu), and the second bonding metal layer includes Tin (Sn). An associated packaging structure is also disclosed.

An electronic device may include a display having a monolithic array of light-emitting diodes mounted to a surface of a substrate layer. The diodes may include contact pads. Driver circuitry may independently drive each of the diodes in the array using drive signals. The driver circuitry may be formed on a driver integrated circuit. Bond pads may be formed on a surface of the integrated circuit. Copper pillars may be grown on the bond pads. In another suitable arrangement, the driver circuitry may be formed on a driver printed circuit board coupled to an interposer by a flexible printed circuit. The interposer may include bond pads and copper pillars grown on the bond pads. The contact pads on each of the diodes may be simultaneously bonded to the copper pillars. A surface of the substrate layer may be patterned to form light redirecting elements if desired.

A semiconductor structure includes an interposer including redistribution wiring interconnects and redistribution insulating layers; a first semiconductor die attached to the interposer through a first array of solder material portions; and a second semiconductor die attached to the interposer through a second array of solder material portions. The interposer includes at least one inductor structure located between an area of the first array of solder material portions and an area of the second array of solder material portions in a plan view and laterally encloses a respective area in the plan view.

A semiconductor package includes a first semiconductor chip having a first surface and a second surface. First connection pads are adjacent to the first surface. A second semiconductor chip has a lower surface facing the first surface of the first semiconductor chip and includes second connection pads, Connection bumps contact the first connection pads and the second connection pads between the first semiconductor chip and the second semiconductor chip. An adhesive layer is interposed between the first semiconductor chip and the second semiconductor chip to at least partially surround the connection bumps. The adhesive layer includes a protruding portion protruding from a side surface of the second semiconductor chip. A barrier structure covers a portion of the first connection pads, partially overlapping the second semiconductor chip on the first surface, and contacting the protruding portion of the adhesive layer.

An integrated circuit package can contain a semiconductor die and provide electrical connections between the semiconductor die and additional electronic components. The integrated circuit package can reduce stress placed on the semiconductor die due to movement of the integrated circuit package due to, for example, temperature changes and/or moisture levels. The integrated circuit package can at least partially mechanically isolate the semiconductor die from the integrated circuit package.