In an embodiment a method includes providing a semiconductor chip, applying a solder metal layer sequence on the semiconductor chip, providing a substrate, applying a metallization layer sequence on the substrate, applying the semiconductor chip on the substrate via the solder metal layer sequence and the metallization layer sequence and heating the applied semiconductor chip on the substrate for fastening the semiconductor chip on the substrate, wherein the solder metal layer sequence includes a first metallic layer including an indium-tin alloy, a barrier layer arranged above the first metallic layer, and a second metallic layer having gold arranged between the barrier layer and the semiconductor chip, and wherein the indium-tin alloy has the following formula: In.sub.xSn.sub.1-x with 0.04≤x≤0.2.

A device wafer is provided that includes a substrate having major and minor surfaces, and a plurality of active devices located at the major surface. A eutectic alloy composition having a first thickness is formed at the minor surface of the substrate. The eutectic alloy composition is partially removed from the minor surface of the substrate such that a second thickness of the eutectic alloy composition remains on the minor surface, the second thickness being less than the first thickness. A bonding layer is deposited over the eutectic alloy composition. The bonding layer is utilized for joining semiconductor components of the device wafer to secondary structures.

A device wafer is provided that includes a substrate having major and minor surfaces, and a plurality of active devices located at the major surface. A eutectic alloy composition having a first thickness is formed at the minor surface of the substrate. The eutectic alloy composition is partially removed from the minor surface of the substrate such that a second thickness of the eutectic alloy composition remains on the minor surface, the second thickness being less than the first thickness. A bonding layer is deposited over the eutectic alloy composition. The bonding layer is utilized for joining semiconductor components of the device wafer to secondary structures.

A method for forming a chip package structure is provided. The method includes disposing a chip over a substrate. The method includes forming a heat-spreading wall structure over the substrate. The heat-spreading wall structure is adjacent to the chip, and there is a first gap between the chip and the heat-spreading wall structure. The method includes forming a first heat conductive layer in the first gap. The method includes forming a second heat conductive layer over the chip. The method includes disposing a heat-spreading lid over the substrate to cover the heat-spreading wall structure, the first heat conductive layer, the second heat conductive layer, and the chip. The heat-spreading lid is bonded to the substrate, the heat-spreading wall structure, the first heat conductive layer, and the second heat conductive layer.

A method for forming a chip package structure is provided. The method includes disposing a chip over a substrate. The method includes forming a heat-spreading wall structure over the substrate. The heat-spreading wall structure is adjacent to the chip, and there is a first gap between the chip and the heat-spreading wall structure. The method includes forming a first heat conductive layer in the first gap. The method includes forming a second heat conductive layer over the chip. The method includes disposing a heat-spreading lid over the substrate to cover the heat-spreading wall structure, the first heat conductive layer, the second heat conductive layer, and the chip. The heat-spreading lid is bonded to the substrate, the heat-spreading wall structure, the first heat conductive layer, and the second heat conductive layer.

A semiconductor device includes a silicon carbide layer, a metal carbide layer arranged over the silicon carbide layer, and a solder layer arranged over and in contact with the metal carbide layer.

In some examples, a system comprises a set of nanoparticles and a set of nanowires extending from the set of nanoparticles.

In some examples, a system comprises a set of nanoparticles and a set of nanowires extending from the set of nanoparticles.

A method of soldering elements together includes providing a substrate having a metal die attach surface, providing a semiconductor die that is configured as a power semiconductor device and having a semiconductor body, a rear side metallization, and a front side layer stack, the front side layer stack having a front side metallization and a contaminant protection layer, arranging the semiconductor die on the substrate with a region of solder material between the die attach surface and the rear side metallization, and performing a soldering process that reflows the region of solder material to form a soldered joint between the metal die attach surface and the rear side metallization, wherein the soldering process comprises applying mechanical pressure to the front side metallization, and wherein the contaminant protection layer is configured to prevent transmission of contaminants into the semiconductor body after the soldering process is completed.

A method for replacing an element of a display device includes: forming a structure with a first liquid layer between a first micro device and a conductive pad of a substrate in which the first micro device is gripped by a sticking force produced by the first liquid layer; evaporating the first liquid layer such that the first micro device is bound to the substrate; determining if the first micro device is malfunctioned or misplaced; removing the first micro device when the first micro device is malfunctioned or misplaced; forming another structure with a second liquid layer between a second micro device and the conductive pad of the substrate in which the second micro device is gripped by a sticking force produced by the second liquid layer; and evaporating the second liquid layer such that the second micro device is bound to the substrate.