A semiconductor device includes: an insulating substrate; a first semiconductor element connected to the insulating substrate; a conductive member disposed on the insulating substrate, and including a first opposing portion and a second opposing portion located opposite each other with respect to the first semiconductor element in plan view; a first wire connected to the first semiconductor element and the first opposing portion; and a second wire connected to the first semiconductor element and the second opposing portion, and located opposite the first wire with respect to a connection point where the first wire and the first semiconductor element are connected to each other in plan view.

A semiconductor device according to the embodiment includes: a frame body having a wall surface; an insulating substrate surrounded by the frame body, the insulating substrate having a first metal layer and a second metal layer on a surface, the second metal layer being located between the first metal layer and the wall surface; a semiconductor chip including an electrode and provided on the first metal layer; and a bonding wire having a first bond portion connected to the electrode, a second bond portion connected to the second metal layer, and an intermediate portion between the first bond portion and the second bond portion; wherein a second angle formed between a second direction in which the second bond portion extends and the wall surface is smaller than a first angle formed between a first direction in which the intermediate portion extends and the wall surface.

A semiconductor device has a substrate and a first semiconductor die disposed over the substrate. A first metal frame is disposed over the substrate around the first semiconductor die. A first metal lid is disposed over the first metal frame. A flap of the first metal lid includes an elastic characteristic to latch onto the first metal frame. An edge of the flap can have a castellated edge. A recess in the first metal frame and a protrusion on the first metal lid can be used to latch the first metal lid onto the first metal frame. A second metal frame and second metal lid can be disposed over an opposite surface of the substrate from the first metal frame.

Embodiments include semiconductor packages and method of forming the semiconductor packages. A semiconductor package includes a package substrate on a substrate, a die on the package substrate, and a conductive stiffener over the package substrate and the substrate. The conductive stiffener surrounds the package substrate, where the conductive stiffener has a top portion and a plurality of sidewalls, and where the top portion is directly disposed on the package substrate, and the sidewalls are vertically disposed on the substrate. The semiconductor package also includes the substrate that has a plurality of conductive pads, where the conductive pads are conductively coupled to a ground source. The conductive stiffener may conductively couple the package substrate to the conductive pads of the substrate. The top portion may have a cavity that surrounds the die, where the top portion is directly disposed on a plurality of outer edges of the package substrate.

A semiconductor module includes a mounting substrate, a transistor mounted on the mounting substrate, a housing configured to house a semiconductor element, a first sealing layer filled in a space inside the housing to seal the transistor, a second sealing layer of a resin material softer than the first sealing layer and layered on the first sealing layer, and a wire electrically connected to the transistor, in which the wire includes a first portion covered with the first sealing layer and a second portion covered with the second sealing layer.

The present disclosure relates to thin-form-factor semiconductor device packages, and methods and systems for forming the same. Embodiments of the disclosure include methods and apparatus for forming semiconductor device packages that include frames that are coated with a layer of a coupling agent on which subsequently layers are formed. The utilization of the coupling agent between the frame and subsequently formed layers enhances the thermo-mechanical reliability of the package frames by mitigating the stress induced by any subsequently formed insulation layers and/or RDLs, and by providing improved coupling between such layers and the relatively smooth surfaces of the frames.

An insulating component includes an insulating substrate, a metal layer, a bond, and a lead terminal. The plate-like insulating substrate has a groove continuous from its upper to side surfaces. The metal layer includes a first metal layer on the upper surface of the insulating substrate and a second metal layer on an inner surface of the groove continuous with the first metal layer. The bond is on an upper surface of the metal layer. The lead terminal is on an upper surface of the first metal layer with the bond in between, and overlaps the grooves. The bond includes a first bond fixing the lead terminal to the first metal layer and a second bond on an upper surface of the second metal layer continuous with the first bond. The groove includes an inner wall having a ridge. The second bond is between the ridge and the lead terminal.

A method for forming a chip package structure is provided. The method includes disposing a chip over a substrate. The method includes forming a heat-spreading wall structure over the substrate. The heat-spreading wall structure is adjacent to the chip, and there is a first gap between the chip and the heat-spreading wall structure. The method includes forming a first heat conductive layer in the first gap. The method includes forming a second heat conductive layer over the chip. The method includes disposing a heat-spreading lid over the substrate to cover the heat-spreading wall structure, the first heat conductive layer, the second heat conductive layer, and the chip. The heat-spreading lid is bonded to the substrate, the heat-spreading wall structure, the first heat conductive layer, and the second heat conductive layer.

A semiconductor device includes a circuit substrate, a semiconductor package, and a metallic cover. The semiconductor package is disposed on the circuit substrate. The metallic cover is disposed over the semiconductor package and over the circuit substrate. The metallic cover comprises a lid and outer flanges. The lid overlies the semiconductor package. The outer flanges are disposed at edges of the lid, are connected with the lid, extend from the lid towards the circuit substrate, and face side surfaces of the semiconductor package. The lid has a first region that is located over the semiconductor package and is thicker than a second region that is located outside a footprint of the semiconductor package.

Several embodiments of the present technology are described with reference to a semiconductor apparatus. In some embodiments of the present technology, a semiconductor apparatus includes a stack of semiconductor dies attached to a thermal transfer structure. The thermal transfer structure conducts heat away from the stack of semiconductor dies. Additionally, the assembly can include molded walls to support the thermal transfer structure.