An integrated circuit package that includes a leadframe and a mold compound encapsulating at least a portion of the leadframe. The mold compound includes a cavity open at a bottom surface of the mold compound that exposes a bottom surface of the leadframe. A thermally conductive and electrically insulating isolation layer is locked within the bottom cavity of the mold compound and contacts the bottom surface of the leadframe.

Systems, apparatuses, and methods relating to memory devices and packaging are described. A device, such as a dual inline memory module (DIMM) or other electronic device package, may include a substrate with a layer of graphene configured to conduct thermal energy (e.g., heat) away from components mounted or affixed to the substrate. In some examples, a DIMM includes an uppermost or top layer of graphene that is exposed to the air and configured to allow connection of memory devices (e.g., DRAMs) to be soldered to the conducting pads of the substrate. The graphene may be in contact with parts of the memory device other than the electrical connections with the conducting pads and may thus be configured as a heat sink for the device. Other thin, conductive layers of may be used in addition to or as an alternative to graphene. Graphene may be complementary to other heat sink mechanisms.

A power module includes a substrate having a dielectric layer, a first power semiconductor device disposed on an upper part of the substrate, and a second power semiconductor device disposed on a lower part of the substrate.

Pre-encapsulated lead frames suitable for use in microelectronic device packages are disclosed. Individual lead frames can include a set of multiple lead fingers arranged side by side with neighboring lead fingers spaced apart from each other by a corresponding gap. An encapsulating compound at least partially encapsulates the set of lead fingers without encapsulating a microelectronic device. The encapsulating compound can generally fill the plurality of gaps between two adjacent lead fingers.

A semiconductor device includes a first and a second semiconductor elements and a wiring board. The first semiconductor element has a first electrode, a second electrode and a third electrode, and current flow between the first electrode and the second electrode is on-off controlled. The second semiconductor element has a fourth electrode, a fifth electrode and a sixth electrode, and current flow between the fourth electrode and the fifth electrode is on-off controlled. The wiring board includes a base, an obverse surface wiring layer, a reverse surface wiring layer, and a metal member inserted in the base to electrically connect the obverse surface wiring layer and the reverse surface wiring layer. The first semiconductor element and the second semiconductor element are connected in series by connecting the second electrode and the fourth electrode. The metal member is in a conduction path between the second electrode and the fourth electrode.

A plastic material substrate has a die mounting location for a semiconductor die. Metallic traces are formed on selected areas of the plastic material substrate, wherein the metallic traces provide electrically-conductive paths for coupling to the semiconductor die. The semiconductor die is attached onto the die mounting location. The semiconductor die attached onto the die mounting location is electrically bonded to selected ones of the metallic traces formed on the plastic material substrate. A package material is molded onto the semiconductor die attached onto the die mounting location.

A semiconductor device includes a switching element, a control element that controls the switching element, an island lead on which the switching element and the control element are mounted, and a plurality of terminal leads. The switching element includes a first electrode, a second electrode and a third electrode, where the first electrode and the second electrode are offset from the third electrode in a first sense of a thickness direction. The island lead has an obverse surface facing in the first sense of the thickness direction and supporting the switching element and the control element. Each terminal lead is electrically connected to the second electrode or the control element. The island lead is spaced apart from the plurality of terminal leads.

A semiconductor device includes a lead frame having a first principal surface which includes a recess, and a second principal surface opposite to the first principal surface, a relay board, disposed in the recess, and having a third principal surface, and a fourth principal surface opposite to the third principal surface, wherein the fourth principal surface opposes a bottom surface of the recess, a first semiconductor chip disposed on the third principal surface, a first conductive material connecting the lead frame and the relay board, and a second conductive material connecting the relay board and the first semiconductor chip. A distance between the second principal surface and the third principal surface is less than or equal to a distance between the second principal surface and the first principal surface.

A gate driver configured to apply a drive voltage signal to a gate of a switching element includes a low-voltage circuit chip and a high-voltage circuit chip. The low-voltage circuit chip includes a low-voltage circuit configured to be actuated by application of a first voltage. The high-voltage circuit chip includes a high-voltage circuit configured to be actuated by application of a second voltage that is higher than the first voltage. The gate driver further includes multiple transformer chips connected in series to each other. The low-voltage circuit chip and the high-voltage circuit chip are connected by the multiple transformer chips and configured to transmit a signal through the multiple transformer chips.

A molded semiconductor package includes: a mold compound; a metal substrate partly embedded in the mold compound; at least one first metal lead partly embedded in the mold compound; an inlay embedded in the mold compound, the inlay comprising a semiconductor die embedded in an electrically insulating body, a first metal structure attached to a first side of the semiconductor die, and a second metal structure attached to a second side of the semiconductor die; and a metal clip at least partly embedded in the mold compound and connecting the second metal structure to the at least one first metal lead. The semiconductor die has a maximum junction temperature higher than a glass transition temperature of the mold compound, the electrically insulating body has a glass transition temperature at or above the maximum junction temperature of the semiconductor die, and the metal substrate is attached to the first metal structure.