A device includes an array of light sources (e.g., micro-LEDs, micro-RCLEDs, micro-laser: micro-SLEDs, or micro-VCSELs), a dielectric layer on the array of light sources, and a set of metal bonding pads (e.g., copper bonding pads) in the dielectric layer. Each metal bonding pad of the set of metal bonding pads is electrically connected to a respective light source of the array of light sources. Each metal bonding pad of the set of metal bonding pads includes a first portion at a bonding surface and characterized by a first lateral cross-sectional area, and a second portion away from the bonding surface and characterized by a second lateral cross-sectional area larger than two times of the first lateral cross-sectional area. The device can be bonded to a backplane that includes a drive circuit through a low annealing temperature hybrid bonding.

A leadframe includes a die pad having arranged thereon a first semiconductor die with an electrically conductive ribbon extending on the first semiconductor die. The first semiconductor die lies intermediate the leadframe and the electrically conductive ribbon. A second semiconductor die is mounted on the electrically conductive ribbon to provide, on the same die pad, a stacked arrangement of the second semiconductor die and the first semiconductor die with the at least one electrically conductive ribbon intermediate the first semiconductor die and the second semiconductor die. Package size reduction can thus be achieved without appreciably affecting the assembly flow of the device.

A semiconductor package comprises a semiconductor substrate, a first metal layer, an adhesive layer, a second metal layer, a rigid supporting layer, and a plurality of contact pads. A thickness of the semiconductor substrate is equal to or less than 50 microns. A thickness of the rigid supporting layer is larger than the thickness of the semiconductor substrate. A thickness of the second metal layer is larger than a thickness of the first metal layer. A method comprises the steps of providing a device wafer; providing a supporting wafer; attaching the supporting wafer to the device wafer via an adhesive layer; and applying a singulation process so as to form a plurality of semiconductor packages.

A semiconductor device includes a semiconductor element, an internal electrode connected to the semiconductor element, a sealing resin covering the semiconductor element and a portion of the internal electrode, and an external electrode exposed from the sealing resin and connected to the internal electrode. The internal electrode includes a wiring layer and a columnar portion, where the wiring layer has a wiring layer front surface facing the back surface of the semiconductor element and a wiring layer back surface facing opposite from the wiring layer front surface in the thickness direction. The columnar portion protrudes in the thickness direction from the wiring layer front surface. The columnar portion has an exposed side surface facing in a direction perpendicular to the thickness direction. The external electrode includes a first cover portion covering the exposed side surface.

An apparatus for transferring an electronic component is configured to transfer an electronic component on a flexible carrier to a target substrate. The apparatus includes a first frame, a second frame, an abutment module, an actuator, and a negative pressure generating device. The abutment module includes an abutting component and a guide. The guide guides a movement of the abutting component. The actuator actuates the abutment module so that the abutting component and the guide are respectively moved between a start position and an end position of an abutment path. The negative pressure generating device is pumped through the abutment module. When the abutment module abuts against the flexible carrier, a negative pressure is generated between the abutment module and the flexible carrier by the negative pressure generating device. The abutting component and the guide are moved simultaneously in at least a portion of the abutment path.

Semiconductor devices having metallization structures including crack-inhibiting structures, and associated systems and methods, are disclosed herein. In one embodiment, a semiconductor device includes a metallization structure formed over a semiconductor substrate. The metallization structure can include a bond pad electrically coupled to the semiconductor substrate via one or more layers of conductive material, and an insulating material—such as a low-κ dielectric material—at least partially around the conductive material. The metallization structure can further include a crack-inhibiting structure positioned beneath the bond pad between the bond pad and the semiconductor substrate. The crack-inhibiting structure can include a barrier member extending vertically from the bond pad toward the semiconductor substrate and configured to inhibit crack propagation through the insulating material.

A display device includes a base layer; a pixel circuit layer disposed on the base layer, the pixel circuit layer including a first transistor; and an insulating layer overlapping the first transistor; a first electrode disposed on the pixel circuit layer, the first electrode electrically connected to the first transistor via a contact hole of the insulating layer; a cover layer disposed on the first electrode, the cover layer overlapping at least a portion of the first electrode; a light emitting element including a first end and a second end electrically connected to the first electrode; a second electrode disposed on the light emitting element, the second electrode electrically connected to the second end of the light emitting element; and a third electrode disposed on the cover layer, the third electrode electrically contacting at least a portion of the first electrode.

The disclosure provides a semiconductor chip suit for driving a display panel. The semiconductor chip includes a first pad group and a second pad group. The first pad group and the second pad group are disposed at a first long side of the semiconductor chip. The first distance from the first pad group to the edge of the first long side is different from the second distance from the second pad group to the edge of the first long side. The first pad group and the second pad group belong to a first pad row disposed at the first long side. The first pad group comprises a plurality of pads which are closer to the middle of the first pad row than the second pad group.

A semiconductor device with improved reliability is provided. The semiconductor device is characterized by its embodiments in that sloped portions are formed on connection parts between a pad and a lead-out wiring portion, respectively. This feature suppresses crack formation in a coating area where a part of the pad is covered with a surface protective film.

A flip-chip LED device includes an epitaxial structure, a first contact electrode, and a second contact electrode. The second contact electrode is disposed on the epitaxial structure and extending toward the first contact electrode. The second contact electrode includes a first curved extension, a second curved extension, a connecting portion, a first straight extension, and a second straight extension. The connecting portion is connected to the first curved extension and to the second curved extension. The first straight extension is connected to the first curved extension. The second straight extension is connected to the second curved extension.