A semiconductor packaging method, a semiconductor assembly and an electronic device are disclosed herein. The semiconductor packaging method comprises forming a first-stage assembly, including: align and fix at least one first-stage device to a target position on a carrier plate by utilizing the self-alignment capability of first-stage alignment solder joints; and while using a clamping board to support an exposed side of the at least one first-stage device, performing injection molding through an opening in the carrier board or the clamping board. The packaging method further comprises align and fix a second-stage device to a target position on the first-stage assembly by utilizing the self-alignment capability of second-level alignment solder joints between the first-stage assembly and the second-stage device. The packaging method improves the operation speed and accuracy of the picking and placing of the first-stage device and the second-stage device, resulting in improved process efficiency and reduced process cost.

A semiconductor device comprises a substrate having a substrate top side, a substrate lateral side, and a substrate bottom side, an electronic device on the substrate top side, and an encapsulant on the substrate top side and contacting a lateral surface of the electronic device. The substrate comprises a conductive structure and a dielectric structure that extends comprising a protrusion in contact with the encapsulant. The conductive structure comprises a lead comprising a lead flank, the lead flank comprising a cavity and a conductive coating on a surface of the lead in the cavity. The conductive structure comprises a pad exposed at the substrate top side, embedded in the dielectric structure, and adjacent to the protrusion, to electrically couple with the electronic device via a first internal interconnect. Other examples and related methods are also disclosed herein.

A semiconductor device comprises a substrate having a substrate top side, a substrate lateral side, and a substrate bottom side, an electronic device on the substrate top side, and an encapsulant on the substrate top side and contacting a lateral surface of the electronic device. The substrate comprises a conductive structure and a dielectric structure that extends comprising a protrusion in contact with the encapsulant. The conductive structure comprises a lead comprising a lead flank, the lead flank comprising a cavity and a conductive coating on a surface of the lead in the cavity. The conductive structure comprises a pad exposed at the substrate top side, embedded in the dielectric structure, and adjacent to the protrusion, to electrically couple with the electronic device via a first internal interconnect. Other examples and related methods are also disclosed herein.

Various semiconductor chip solder bump and underbump metallization (UBM) structures and methods of making the same are disclosed. In one aspect, a method is provided that includes forming a first underbump metallization layer on a semiconductor chip is provided. The first underbump metallization layer has a hub, a first portion extending laterally from the hub, and a spoke connecting the hub to the first portion. A polymer layer is applied to the first underbump metallization layer. The polymer layer includes a first opening in alignment with the hub and a second opening in alignment with the spoke. A portion of the spoke is removed via the second opening to sever the connection between the hub and the first portion.

A semiconductor module includes a printed wiring board and a semiconductor device. The printed wiring board includes a plurality of lands bonded to the semiconductor device via solder, and a solder resist. The plurality of lands includes a first land positioned in a vicinity of an outer edge of the insulating substrate and including a first edge portion, a second edge portion, a third edge portion, and a fourth edge portion. The first edge portion and the second edge portion are configured not to overlap with the solder resist and the third edge portion and the fourth edge portion are configured to overlap with the solder resist.

The purpose of the present invention is to provide an electronic circuit connection method and an electronic circuit capable of improving the reliability of electrical connection. A connection method for an electronic circuit 100 includes: a process of forming a first metal bumps 30 and a second metal bump 40, each of which has a cone shape; and a process of joining a first electrode pad 12 and a third electrode pad 22 by the first metal bump 30 and joining a second electrode pad 13 and a fourth electrode pad 23 by the second metal bump 40, wherein at least one region of between a first region 11a and a second region 11b in a first connection surface 11 and between a third region 21a and a fourth region 21b in a second connection surface 21 has a step 11c, and the first metal bump 30 and the second metal bump 40 have different heights so as to correct a height H1 of the step 11c.

A substrate that includes a core layer comprising a first surface and a second surface, at least one first dielectric layer located over a first surface of the core layer, at least one second dielectric layer located over a second surface of the core layer, high-density interconnects located over a surface of the at least one second dielectric layer, interconnects located over the surface of the at least one second dielectric layer, and a solder resist layer located over the surface of the at least one second dielectric layer. A first portion of the solder resist layer that is touching the high-density interconnects includes a first thickness that is equal or less than a thickness of the high-density interconnects. A second portion of the solder resist layer that is touching the interconnects includes a second thickness that is greater than a thickness of the interconnects.

A chip package includes a redistribution layer, a chip, and an encapsulation member. The redistribution layer includes an insulation part, a plurality of first pads and a plurality of second pads, where the insulation part has a first surface, a second surface opposite to the first surface, and a side surface between the first surface and the second surface. The first pads and the second pads are located at the first surface and the second surface respectively. The chip is disposed on the first surface and electrically connected to the first pads. The encapsulation member wraps the chip and the redistribution layer, and covers the first surface and the side surface, where the encapsulation member exposes the second pads, and the encapsulation member is not flush with the first surface and the side surface.

The present invention relates to a three-dimensional integrated package device for a high-voltage silicon carbide power module, comprising a source substrate, first chip submodules, a first driving terminal, a first driving substrate, a ceramic housing, a metal substrate, a water inlet, a water outlet, second chip submodules, a second driving terminal, a second driving substrate and a drain substrate from top to bottom; and each first chip submodule is composed of a driving connection substrate, a power source metal block, a first driving gate metal post, second driving gate metal posts, a silicon carbide bare chip, an insulation structure and the like. A three-dimensional integrated half-bridge structure is adopted to greatly reduce corresponding parasitic parameters.

The present invention relates to a three-dimensional integrated package device for a high-voltage silicon carbide power module, comprising a source substrate, first chip submodules, a first driving terminal, a first driving substrate, a ceramic housing, a metal substrate, a water inlet, a water outlet, second chip submodules, a second driving terminal, a second driving substrate and a drain substrate from top to bottom; and each first chip submodule is composed of a driving connection substrate, a power source metal block, a first driving gate metal post, second driving gate metal posts, a silicon carbide bare chip, an insulation structure and the like. A three-dimensional integrated half-bridge structure is adopted to greatly reduce corresponding parasitic parameters.