The present invention relates to a method of forming a joint bonding together two solid objects and joints made by the method, where the joint is formed by a layer of a binary system which upon heat treatment forms a porous, coherent and continuous single solid-solution phase extending across a bonding layer of the joint.

The present invention relates to a method of forming a joint bonding together two solid objects and joints made by the method, where the joint is formed by a layer of a binary system which upon heat treatment forms a porous, coherent and continuous single solid-solution phase extending across a bonding layer of the joint.

Disclosed herein is a method of forming an electrical connecting structure having nano-twins copper. The method includes the steps of (i) forming a first nano-twins copper layer including a plurality of nano-twins copper grains; (ii) forming a second nano-twins copper layer including a plurality of nano-twins copper grains; and (iii) joining a surface of the first nano-twins copper layer with a surface of the second nano-twins copper layer, such that at least a portion of the first nano-twins copper grains grow into the second nano-twins copper layer, or at least a portion of the second nano-twins copper grains grow into the first nano-twins copper layer. An electrical connecting structure having nano-twins copper is provided as well.

The invention relates to a positioning device for positioning a substrate, in particular a wafer, comprising: a process chamber; a base body; a carrier element which comprises a support for supporting the substrate, the carrier element being arranged above the base body and formed movable in terms of distance from the base body; and a holder for an additional substrate, in particular an additional wafer or a mask, the holder being arranged opposite the carrier element; wherein there is, between the base body and the carrier element, a sealed-off cavity to which a pressure, in particular a negative pressure, can be applied so as to prevent undesired movement of the carrier element as a result of the action of an external force.

A semiconductor device includes: a carrier having a die pad and a contact; a semiconductor die having opposing first and second main sides and being attached to the die pad by a first solder joint such that the second main side faces the die pad; and a contact clip having a first contact region and a second contact region. The first contact is attached to the first main side by a second solder joint. The second contact region is attached to the contact by a third solder joint. The first contact region has a convex shape facing towards the first main side such that a distance between the first main side and the first contact region increases from a base of the convex shape towards an edge of the first contact region. The base runs along a line that is substantially perpendicular to a longitudinal axis of the contact clip.

In a method for connecting components during production of power electronics modules or assemblies, surfaces of the components have a metallic surface layer upon supply, or are furnished therewith, wherein the layer has a surface that is smooth enough to allow direct bonding or is smoothed to obtain a surface that is smooth enough to allow direct bonding. The surface layers of the surfaces that are to be connected are then pressed against each other with a pressure of at least 5 MPa at elevated temperature, so that they are joined to each other, forming a single layer. The method enables simple, rapid connection of even relatively large contact surfaces, which satisfies the high requirements of power electronics modules.

A semiconductor device includes a first die; a second die attached over the first die; a metal enclosure directly contacting and extending between the first die and the second die, wherein the first metal enclosure is continuous and encircles a set of one or more internal interconnects, wherein the first metal enclosure is configured to electrically connect to a first voltage level; and a second metal enclosure directly contacting and extending between the first die and the second die, wherein the second metal enclosure is continuous and encircles the first metal enclosure and is configured to electrically connect to a second voltage level; wherein the first metal enclosure and the second metal enclosure are configured to provide an enclosure capacitance encircling the set of one or more internal interconnects for shielding signals on the set of one or more internal interconnects.

A copper paste for pressureless bonding is a copper paste for pressureless bonding, containing: metal particles; and a dispersion medium, in which the metal particles include sub-micro copper particles having a volume average particle diameter of greater than or equal to 0.01 μm and less than or equal to 0.8 μm, and micro copper particles having a volume average particle diameter of greater than or equal to 2.0 μm and less than or equal to 50 μm, and the dispersion medium contains a solvent having a boiling point of higher than or equal to 300° C., and a content of the solvent having a boiling point of higher than or equal to 300° C. is greater than or equal to 2 mass % on the basis of a total mass of the copper paste for pressureless bonding.

A manufacturing method includes the step of forming a diced semiconductor wafer (10) including semiconductor chips (11) from a semiconductor wafer (W) typically on a dicing tape (T1). The diced semiconductor wafer (10) on the dicing tape (T1) is laminated with a sinter-bonding sheet (20). The semiconductor chips (11) each with a sinter-bonding material layer (21) derived from the sinter-bonding sheet (20) are picked up typically from the dicing tape (T1). The semiconductor chips (11) each with the sinter-bonding material layer are temporarily secured through the sinter-bonding material layer (21) to a substrate. Through a heating process, sintered layers are formed from the sinter-bonding material layers (21) lying between the temporarily secured semiconductor chips (11) and the substrate, to bond the semiconductor chips (11) to the substrate. The semiconductor device manufacturing method is suitable for efficiently supplying a sinter-bonding material to individual semiconductor chips while reducing loss of the sinter-bonding material.

A stacked device includes a stacked structure in which a plurality of semiconductors are electrically connected to each other, the semiconductor includes a surface on which a plurality of terminals are provided, the plurality of terminals include a terminal that bonds and electrically connects the semiconductors to each other and a terminal that bonds the semiconductors to each other and does not electrically connect the semiconductors to each other, an area ratio of the plurality of terminals on the surface of the semiconductor is 40% or higher, and an area ratio of the terminals that bond and electrically connect the semiconductors to each other among the plurality of terminals is lower than 50%.