Structures and methods for directly testing a semiconductor wafer having micro-solder connections. According to one embodiment, a method forms a pattern of micro-solder connections coupled with a through substrate via (TSV) that can be directly tested by electrical probing, without the use of a testing interposer. According to another embodiment, a method tests the pattern of micro-solder connections. According to another embodiment, a novel electrical probe tip structure has contacts on the same pitch as the pattern of micro-solder connections.

A light emitting device package according to an embodiment may include a first package body including first and second openings passing through the upper surface and lower surface thereof; a second package body disposed on the first package body and including a third opening passing through the upper surface and lower surface thereof; a light emitting device disposed in the third opening; a first resin disposed between the upper surface of the first package body and the light emitting device; and a second resin disposed in the third opening. According to the embodiment, the upper surface of the first package body may be coupled to the lower surface of the second package body, the first package body may include a recess recessed from the upper surface of the first package body to the lower surface of the first package body, the first resin may be disposed in the recess, the first resin and the second resin include materials different from each other, and the first resin may be in contact with the light emitting device and the second resin.

A light emitting device package according to an embodiment may include a first package body including first and second openings passing through the upper surface and lower surface thereof; a second package body disposed on the first package body and including a third opening passing through the upper surface and lower surface thereof; a light emitting device disposed in the third opening; a first resin disposed between the upper surface of the first package body and the light emitting device; and a second resin disposed in the third opening. According to the embodiment, the upper surface of the first package body may be coupled to the lower surface of the second package body, the first package body may include a recess recessed from the upper surface of the first package body to the lower surface of the first package body, the first resin may be disposed in the recess, the first resin and the second resin include materials different from each other, and the first resin may be in contact with the light emitting device and the second resin.

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 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 quantum device includes a chip including a superconducting circuit, a first wiring substrate, a second wiring substrate, first connection portions connecting the chip and a wiring layer on a first surface of the first wiring substrate and second connection portions connecting the second wiring substrate and a wiring layer on a second surface of the first wiring substrate, wherein one or more second connection portions arranged in a first row as viewed from the edge of the first substrate are provided at positions corresponding respectively to one or more of the first connection portions arranged in a first row as viewed from the edge and are arranged closer to the edge than the first connection portions arranged in the first row.

A semiconductor composite structure includes an electrically conductive bump, and a patterned bonding layer. The electrically conductive bump includes a body portion for being electrically connected to a metal layer of a semiconductor substrate, and a contact portion disposed on the body portion opposite to the metal layer. The patterned bonding layer is disposed on the contact portion opposite to the body portion, and includes an electrically conductive portion and a recess portion depressed relative to the electrically conductive portion. An etching selectivity ratio of the conductive portion relative to the contact portion is greater than 1. A method for making the semiconductor composite structure and a semiconductor device are also disclosed.

A semiconductor composite structure includes an electrically conductive bump, and a patterned bonding layer. The electrically conductive bump includes a body portion for being electrically connected to a metal layer of a semiconductor substrate, and a contact portion disposed on the body portion opposite to the metal layer. The patterned bonding layer is disposed on the contact portion opposite to the body portion, and includes an electrically conductive portion and a recess portion depressed relative to the electrically conductive portion. An etching selectivity ratio of the conductive portion relative to the contact portion is greater than 1. A method for making the semiconductor composite structure and a semiconductor device are also disclosed.

The semiconductor memory device includes: a first substrate including a peripheral circuit, first conductive contact patterns connected to the peripheral circuit, and a first upper insulating layer having grooves exposing the first conductive contact patterns; a second substrate including a memory cell array, a second upper insulating layer disposed on the memory cell array, the second upper insulating layer formed between the memory cell array and the first upper insulating layer, second conductive contact patterns protruding through the second upper insulating layer into an opening of the grooves; and conductive adhesive patterns filling the grooves to connect the second conductive contact patterns to the first conductive contact patterns.

The semiconductor memory device includes: a first substrate including a peripheral circuit, first conductive contact patterns connected to the peripheral circuit, and a first upper insulating layer having grooves exposing the first conductive contact patterns; a second substrate including a memory cell array, a second upper insulating layer disposed on the memory cell array, the second upper insulating layer formed between the memory cell array and the first upper insulating layer, second conductive contact patterns protruding through the second upper insulating layer into an opening of the grooves; and conductive adhesive patterns filling the grooves to connect the second conductive contact patterns to the first conductive contact patterns.