A semiconductor package includes a first semiconductor chip on a wiring structure, a plurality of internal terminals between the wiring structure and the first semiconductor chip; a high thermal conductivity layer is between the wiring structure and the first semiconductor chip; and an encapsulator on the high thermal conductivity layer and contacting the second semiconductor chip. Sidewalls of at least the wiring structure and the encapsulator are substantially coplanar.

A detection structure and a detection method are provided. The method includes the following. A display backplane, a detection circuit board, and a detection light-emitting diode (LED) chip are provided. The detection circuit board is disposed on the display backplane, to connect a first detection line on the detection circuit board with a first contact electrode and connect a second detection line on the detection circuit board with a second contact electrode. A drive signal is output via the display backplane to the first detection line and the second detection line. A contact electrode pair on the display backplane corresponding to the detection LED chip is determined to be abnormal on condition that the detection LED chip is unlighted.

A detection structure and a detection method are provided. The method includes the following. A display backplane, a detection circuit board, and a detection light-emitting diode (LED) chip are provided. The detection circuit board is disposed on the display backplane, to connect a first detection line on the detection circuit board with a first contact electrode and connect a second detection line on the detection circuit board with a second contact electrode. A drive signal is output via the display backplane to the first detection line and the second detection line. A contact electrode pair on the display backplane corresponding to the detection LED chip is determined to be abnormal on condition that the detection LED chip is unlighted.

A detection method and a detection structure for a display backplane is provided in the disclosure. The detection method includes the following. The display backplane is provided. The display backplane is provided with a contact electrode pair. A detection structure is provided. The detection structure includes a light-emitting element and a detection circuit configured to conduct an electrical signal to the light-emitting element. The detection structure is assembled on the display backplane to connect the detection circuit to the contact electrode pair. A drive electrical signal is outputted to the contact electrode pair. If the light-emitting element does not emit light, the contact electrode pair is determined as a fault point.

A detection method and a detection structure for a display backplane is provided in the disclosure. The detection method includes the following. The display backplane is provided. The display backplane is provided with a contact electrode pair. A detection structure is provided. The detection structure includes a light-emitting element and a detection circuit configured to conduct an electrical signal to the light-emitting element. The detection structure is assembled on the display backplane to connect the detection circuit to the contact electrode pair. A drive electrical signal is outputted to the contact electrode pair. If the light-emitting element does not emit light, the contact electrode pair is determined as a fault point.

A method of manufacturing a semiconductor package includes forming a plurality of trenches at a first surface of a silicon substrate, forming a conductive pad inside each of the plurality of trenches, forming a redistribution layer on the first surface of the silicon substrate, forming an external connection terminal on a first surface of the redistribution layer, removing the silicon substrate to expose each conductive pad, mounting a semiconductor chip to be connected to the conductive pads, and forming an encapsulant to cover at least one surface of the semiconductor chip.

A method of manufacturing a semiconductor package includes forming a plurality of trenches at a first surface of a silicon substrate, forming a conductive pad inside each of the plurality of trenches, forming a redistribution layer on the first surface of the silicon substrate, forming an external connection terminal on a first surface of the redistribution layer, removing the silicon substrate to expose each conductive pad, mounting a semiconductor chip to be connected to the conductive pads, and forming an encapsulant to cover at least one surface of the semiconductor chip.

Solder-pinning metal pads for electronic components and techniques for use thereof to mitigate de-wetting are provided. In one aspect, a structure includes: a substrate; and a solder pad on the substrate, wherein the solder pad has sidewalls extending up from a surface thereof. For instance, the sidewalls can be present at edges of the solder pad, or inset from the edges of the solder pad. The sidewalls can be vertical or extend up from the solder pad at an angle. The sidewalls can be formed from the same material or a different material as the solder pad. A method is also provided that includes forming a solder pad on a substrate, the solder pad comprising sidewalls extending up from a surface thereof.

Solder-pinning metal pads for electronic components and techniques for use thereof to mitigate de-wetting are provided. In one aspect, a structure includes: a substrate; and a solder pad on the substrate, wherein the solder pad has sidewalls extending up from a surface thereof. For instance, the sidewalls can be present at edges of the solder pad, or inset from the edges of the solder pad. The sidewalls can be vertical or extend up from the solder pad at an angle. The sidewalls can be formed from the same material or a different material as the solder pad. A method is also provided that includes forming a solder pad on a substrate, the solder pad comprising sidewalls extending up from a surface thereof.

Devices and methods that can facilitate hybrid under-bump metallization components are provided. According to an embodiment, a device can comprise an under-bump metallization component that can comprise a superconducting interconnect component and a solder wetting component. The device can further comprise a solder bump that can be coupled to the superconducting interconnect component and the solder wetting component. In some embodiments, the superconducting interconnect component can comprise a hermetically sealed superconducting interconnect component.