Semiconductor devices including electrically-isolated extensions and associated systems and methods are disclosed herein. An electrically-isolated extension may be coupled to a corresponding connection pad that is attached to a surface of a device. The electrically-isolated extensions may extend at least partially through one or more layers at or near the surface and toward a substrate or an inner portion thereof.

A semiconductor device including an insulating circuit board. The insulating circuit board has an insulating plate, a plurality of circuit patterns disposed on a front surface of the insulating plate, any adjacent two of the circuit patterns having a gap therebetween, each circuit pattern having at least one corner, each corner being in a corner area that covers the corner and a portion of each gap adjacent to the corner, and a buffer material containing resin, applied at a plurality of corner areas, to fill the gaps in the plurality of corner areas.

The present disclosure provides a chip package structure having a heat sink and a method making the same. The method includes: bonding a chip to a top surface of a package substrate and forming a heat-conducting lead having an arc-shape and placed on the chip in a vertical direction, a first end of the heat-conducting lead is connected with a surface of the chip, and a second end is connected with a solder ball; forming a plastic package material layer that protects the chip and the heat-conducting lead; forming a heat-conducting adhesive layer on the surface of the plastic package material layer, where the heat-conducting adhesive layer is connected with the solder ball on the second end of the heat-conducting lead; and forming a heat dissipation layer on a surface of the heat-conducting adhesive layer. With the present disclosure, the heat dissipation efficiency of the chip is effectively improved.

The disclosure provides an electronic device including a substrate, a first semiconductor element, and a first protective structure. The first semiconductor element is disposed on the substrate and electrically connected to the substrate. The first semiconductor element has a first surface away from the substrate. The first protective structure covers at least a portion of the first surface.

According to an exemplary embodiment, a semiconductor component includes a chip carrier, a semiconductor chip mounted on the chip carrier, and a chip package made of potting compound. The potting compound only partially surrounds the semiconductor chip, such that at least part of an upper side of the semiconductor chip is not covered by the potting compound. The semiconductor component further includes a clip that is mechanically connected to the upper side of the semiconductor chip.

The present disclosure provides a chip package structure having a heat sink and a method making the same. The method includes: bonding a chip to a top surface of a package substrate and forming a heat-conducting lead having an arc-shape and placed on the chip in a vertical direction, a first end of the heat-conducting lead is connected with a surface of the chip, and a second end is connected with a solder ball; forming a plastic package material layer that protects the chip and the heat-conducting lead; forming a heat-conducting adhesive layer on the surface of the plastic package material layer, where the heat-conducting adhesive layer is connected with the solder ball on the second end of the heat-conducting lead; and forming a heat dissipation layer on a surface of the heat-conducting adhesive layer. With the present disclosure, the heat dissipation efficiency of the chip is effectively improved.

Provided is a curable granular silicone composition which has hot-melt properties, is excellent in terms of handleability and curability in overmolding and the like, and gives cured objects and the like highly inhibited from taking a color at high temperatures. The curable granular silicone composition comprises: (A) organopolysiloxane resin fine particles which do not have hot-melt properties and have a curing-reactive functional group containing a carbon-carbon double bond and in which siloxane units represented by RSiO.sub.3/2 (where R is a monovalent organic group) or SiO.sub.4/2 account for at least 20 mol % of all the siloxane units; (B) a liquid, linear or branched organopolysiloxane having, in the molecule, at least two curing-reactive functional groups containing a carbon-carbon double bond; (C) a hardener; and (D) a functional filler. The composition as a whole has hot-melt properties. Uses of the curable granular silicone composition are also disclosed.

A semiconductor module, including: plurality of output elements provided to constitute an upper arm and a lower arm; a resin case provided surrounding an accommodation space for accommodating the output elements; an arm-to-arm wiring line for connecting the upper arm with the lower arm; an output terminal, which is connected to the arm-to-arm wiring line and is for outputting output currents from the output elements to a load being external to the semiconductor module; a sense terminal, which is connected to the arm-to-arm wiring line and is for detecting currents that flow in the output elements; and an inductor provided between a connection point for connecting the arm-to-arm wiring line with the output terminal, and the output terminal is provided. An inductance of the inductor is 1 μH or more.

A polyamideimide resin containing a structural unit (Ia) represented by a formula shown below, and a structural unit (IIa) represented by a formula shown below. In the formula (Ia), each X independently represents a hydrogen atom, or at least one substituent selected from the group consisting of halogen atoms, alkyl groups of 1 to 9 carbon, atoms, and alkoxy groups and hydroxyalkyl groups of 1 to 9 carbon atoms. In the formula (IIa), each R independently represents a hydrogen atom, or at least one substituent selected from the group consisting of alkyl groups of 1 to 9 carbon atoms, alkoxy groups of 1 to 9 carbon atoms and halogen atoms, and n represents an integer of 1 to 6.

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In an embodiment, a method includes forming a conductive feature adjacent to a substrate; treating the conductive feature with a protective material, the protective material comprising an inorganic core with an organic coating around the inorganic core, the treating the conductive feature comprising forming a protective layer over the conductive feature; and forming an encapsulant around the conductive feature and the protective layer. In another embodiment, the method further includes, before forming the encapsulant, rinsing the protective layer with water. In another embodiment, the protective layer is selectively formed over the conductive feature.