A multilayer composite bonding material for transient liquid phase bonding a semiconductor device to a metal substrate includes thermal stress compensation layers sandwiched between a pair of bonding layers. The thermal stress compensation layers may include a core layer with a first stiffness sandwiched between a pair of outer layers with a second stiffness that is different than the first stiffness such that a graded stiffness extends across a thickness of the thermal stress compensation layers. The thermal stress compensation layers have a melting point above a sintering temperature and the bonding layers have a melting point below the sintering temperature. The graded stiffness across the thickness of the thermal stress compensation layers compensates for thermal contraction mismatch between the semiconductor device and the metal substrate during cooling from the sintering temperature to ambient temperature.

A display device according to an embodiment of the present invention includes: an electrode; a light-emitting layer formed on the electrode; and a metal-containing film formed on the light-emitting layer and containing a first metallic element. The metal-containing film includes a metal layer forming an interface of the metal-containing film on the side of the light-emitting layer, formed of a simple substance of the first metallic element or an alloy of the first metallic element and a second metallic element, and a light-transmitting oxide layer forming an interface of the metal-containing film on the opposite side from the interface on the side of the light-emitting layer, formed of an oxide of the first metallic element, and having a light-transmitting property.

A method for applying a bonding layer that is comprised of a basic layer and a protective layer on a substrate with the following method steps: application of an oxidizable basic material as a basic layer on a bonding side of the substrate, at least partial covering of the basic layer with a protective material that is at least partially dissolvable in the basic material as a protective layer. In addition, the invention relates to a corresponding substrate.

A method for applying a bonding layer that is comprised of a basic layer and a protective layer on a substrate with the following method steps: application of an oxidizable basic material as a basic layer on a bonding side of the substrate, at least partial covering of the basic layer with a protective material that is at least partially dissolvable in the basic material as a protective layer. In addition, the invention relates to a corresponding substrate.

A method for applying a bonding layer that is comprised of a basic layer and a protective layer on a substrate with the following method steps: application of an oxidizable basic material as a basic layer on a bonding side of the substrate, at least partial covering of the basic layer with a protective material that is at least partially dissolvable in the basic material as a protective layer. In addition, the invention relates to a corresponding substrate.

A method for applying a bonding layer that is comprised of a basic layer and a protective layer on a substrate with the following method steps: application of an oxidizable basic material as a basic layer on a bonding side of the substrate, at least partial covering of the basic layer with a protective material that is at least partially dissolvable in the basic material as a protective layer. In addition, the invention relates to a corresponding substrate.

A power module is fabricated, employing a clad metal that is formed by pressure-laminating aluminum and copper, in such a manner that the aluminum layer of the clad metal is bonded such as by ultrasonic bonding to the surface electrode of the power semiconductor chip and a wire is bonded to the copper layer thereof to establish electrical circuit. The clad metal is thermally treated in advance at a temperature higher than the operating temperature of the power semiconductor chip to sufficiently form intermetallic compounds at the interface between the aluminum layer and the copper layer for the intermetallic compounds so as not to grow in thickness after the bonding processes.

According to various embodiments, a method for processing a substrate may include: processing a plurality of device regions in a substrate separated from each other by dicing regions, each device region including at least one electronic component; wherein processing each device region of the plurality of device regions includes: forming a recess into the substrate in the device region, wherein the recess is defined by recess sidewalls of the substrate, wherein the recess sidewalls are arranged in the device region; forming a contact pad in the recess to electrically connect the at least one electronic component, wherein the contact pad has a greater porosity than the recess sidewalls; and singulating the plurality of device regions from each other by dicing the substrate in the dicing region.

According to various embodiments, a method for processing a substrate may include: processing a plurality of device regions in a substrate separated from each other by dicing regions, each device region including at least one electronic component; wherein processing each device region of the plurality of device regions includes: forming a recess into the substrate in the device region, wherein the recess is defined by recess sidewalls of the substrate, wherein the recess sidewalls are arranged in the device region; forming a contact pad in the recess to electrically connect the at least one electronic component, wherein the contact pad has a greater porosity than the recess sidewalls; and singulating the plurality of device regions from each other by dicing the substrate in the dicing region.

A lead-free, antimony-free solder alloy_suitable for use in electronic soldering applications. The solder alloy comprises (a) from 1 to 4 wt. % silver; (b) from 0.5 to 6 wt. % bismuth; (c) from 3.55 to 15 wt. % indium, (d) 3 wt. % or less of copper; (e) one or more optional elements and the balance tin, together with any unavoidable impurities.