A device includes: a chip; a support member; an adhesive layer disposed on the support member; and a wire electrically connected to the sensor chip on a side face of the sensor chip. Herein the adhesive layer includes a material exhibiting a dilatancy property in which a shear stress increases in a multi-dimensional function as a shear rate increases.

According to an aspect, a semiconductor power module includes a substrate, a semiconductor device coupled to the substrate, a bond wire coupled to the semiconductor device, and a first molding material layer disposed on the substrate. The first molding material layer encapsulates a first portion of the bond wire. The bond wire has a second portion disposed outside of the first molding material layer. The semiconductor power module includes a second molding material layer disposed on the first molding material layer. The second molding material layer encapsulates the second portion of the bond wire. The second molding material layer has a hardness less than a hardness of the second molding material layer.

According to an aspect, a semiconductor power module includes a substrate, a semiconductor device coupled to the substrate, a bond wire coupled to the semiconductor device, and a first molding material layer disposed on the substrate. The first molding material layer encapsulates a first portion of the bond wire. The bond wire has a second portion disposed outside of the first molding material layer. The semiconductor power module includes a second molding material layer disposed on the first molding material layer. The second molding material layer encapsulates the second portion of the bond wire. The second molding material layer has a hardness less than a hardness of the second molding material layer.

A method of and system for manufacturing an electronic device, a curable conductive adhesive for use in the same, and an electronic device are disclosed. The method includes printing a conductive adhesive onto pads at ends of traces on a substrate, placing one or more components having a non-standard size and/or shape onto the pads with the conductive adhesive thereon, and after the component(s) have been placed onto the pads, curing the conductive adhesive at a predetermined temperature or with light having a predetermined wavelength (band). The system comprises a printer configured to print a conductive adhesive onto pads at ends of traces on a substrate, a surface mounting machine configured to place one or more components having a non-standard size and/or shape onto the pads with the conductive adhesive thereon, and a curing station configured to cure the conductive adhesive after the component(s) have been placed onto the pads.

A method of and system for manufacturing an electronic device, a curable conductive adhesive for use in the same, and an electronic device are disclosed. The method includes printing a conductive adhesive onto pads at ends of traces on a substrate, placing one or more components having a non-standard size and/or shape onto the pads with the conductive adhesive thereon, and after the component(s) have been placed onto the pads, curing the conductive adhesive at a predetermined temperature or with light having a predetermined wavelength (band). The system comprises a printer configured to print a conductive adhesive onto pads at ends of traces on a substrate, a surface mounting machine configured to place one or more components having a non-standard size and/or shape onto the pads with the conductive adhesive thereon, and a curing station configured to cure the conductive adhesive after the component(s) have been placed onto the pads.

MicroLED devices can be transferred in large numbers to form microLED displays using processes such as pick-and-place, thermal adhesion transfer, or fluidic transfer. A blanket solder layer can be applied to connect the bond pads of the microLED devices to the terminal pads of a support substrate. After heating, the solder layer can connect the bond pads with the terminal pads in vicinity of each other. The heated solder layer can correct misalignments of the microLED devices due to the transfer process.

MicroLED devices can be transferred in large numbers to form microLED displays using processes such as pick-and-place, thermal adhesion transfer, or fluidic transfer. A blanket solder layer can be applied to connect the bond pads of the microLED devices to the terminal pads of a support substrate. After heating, the solder layer can connect the bond pads with the terminal pads in vicinity of each other. The heated solder layer can correct misalignments of the microLED devices due to the transfer process.

A power semiconductor module includes: a substrate including first, second, and third metal patterns separated from each other, a semiconductor element located on the substrate, a lead frame located on the substrate and including first, second, third, and fourth bodies; a first terminal connected to the first body, a second terminal connected to the second body, and a third common terminal that connects the third body and the fourth body, wherein a length of the third common terminal is longer than that of the first and second terminals.

The display device can include a substrate; a barrier rib disposed on the substrate and having an assembly hole; a semiconductor light emitting device in the assembly hole; and an adhesive part between the substrate and the semiconductor light emitting device within the assembly hole. The adhesive part can include adhesive particles in contact with each other.

An improvement is achieved in the performance of a semiconductor device. A second component mounting portion over which a first electronic component is mounted is connected to a coupling portion of a lead frame via a suspension lead. The suspension lead has a first portion between the second component mounting portion and the coupling portion and a second portion between the first portion and the coupling portion. The second portion has a third portion connected to the first portion and having a width smaller than a width of the first portion, a fourth portion connected to the first portion and having a width smaller than the width of the first portion, and a through hole (opening) located between the third and fourth portions. Each of the first, third, and fourth portions has the same thickness. After a sealing body is formed, a cutting jig is pressed against the suspension lead to cut the suspension lead.