A semiconductor device includes: a semiconductor chip; a case having a frame portion that has an inner wall portion surrounding an housing area in which the semiconductor chip is disposed; a buffer member provided on at last part of the inner wall portion of the case on a side of the housing area; a low expansion member provided on said at least part of the inner wall portion with the buffer member interposed therebetween on the side of the housing area; and a sealing member that seals the housing area, wherein the buffer member has a smaller elastic modulus than the case and the sealing member, and wherein the low expansion member has a smaller linear expansion coefficient than the case and the sealing member.

A semiconductor device includes: a semiconductor chip; a case having a frame portion that has an inner wall portion surrounding an housing area in which the semiconductor chip is disposed; a buffer member provided on at last part of the inner wall portion of the case on a side of the housing area; a low expansion member provided on said at least part of the inner wall portion with the buffer member interposed therebetween on the side of the housing area; and a sealing member that seals the housing area, wherein the buffer member has a smaller elastic modulus than the case and the sealing member, and wherein the low expansion member has a smaller linear expansion coefficient than the case and the sealing member.

A solder material for use in electronic assembly, the solder material comprising: solder layers; and a core layer comprising a core material, the core layer being sandwiched between the solder layers, wherein: the thermal conductivity of the core material is greater than the thermal conductivity of the solder.

A solder material for use in electronic assembly, the solder material comprising: solder layers; and a core layer comprising a core material, the core layer being sandwiched between the solder layers, wherein: the thermal conductivity of the core material is greater than the thermal conductivity of the solder.

A semiconductor device manufacturing method, includes: a preparing process for preparing a conductive plate, a semiconductor chip arranged over the conductive plate with a first bonding material therebetween, and a connection terminal including a bonding portion arranged over the semiconductor chip with a second bonding material therebetween; a first jig arrangement process for arranging a first guide jig, through which a first guide hole pierces, over the conductive plate, such that the first guide hole corresponds to the bonding portion in a plan view of the semiconductor device; and a first pressing process for inserting a pillar-shaped pressing jig, which includes a pressing portion at a lower end portion thereof, into the first guide hole, and pressing the bonding portion of the connection terminal to a side of the conductive plate with the pressing portion.

The invention relates to a metal layer stack for use in electronic components, in particular as a spacer in power electronic components, comprising n bulk metal layers and n or n+1 contact material layers, wherein the bulk metal layers and the contact material layers are stacked in an alternating manner and n is at least two. Additionally, the invention relates to a process for preparing the metal layer stack and a semiconductor module comprising such a metal layer stack.

A regulating jig that includes one end, the other end, and a groove having opposite regulating surfaces formed therein, between the one end and the other end is set on a positioning jig. At this time, the regulating surfaces are positioned at sides of the regulating member entering the groove, and the one end and the other end of the regulating jig are positioned on respective opposite sides of the opening edge of an opening area of the positioning jig. Then, a base substrate, a solder sheet, and an insulated circuit substrate are heated to bond the insulated circuit substrate to the base substrate.

A method of forming a chip assembly may include forming a plurality of cavities in a carrier; The method may further include arranging a die attach liquid in each of the cavities; arranging a plurality of chips on the die attach liquid, each chip comprising a rear side metallization and a rear side interconnect material disposed over the rear side metallization, wherein the rear side interconnect material faces the carrier; evaporating the die attach liquid; and after the evaporating the die attach liquid, fixing the plurality of chips to the carrier.

A method of forming a chip assembly may include forming a plurality of cavities in a carrier; The method may further include arranging a die attach liquid in each of the cavities; arranging a plurality of chips on the die attach liquid, each chip comprising a rear side metallization and a rear side interconnect material disposed over the rear side metallization, wherein the rear side interconnect material faces the carrier; evaporating the die attach liquid; and after the evaporating the die attach liquid, fixing the plurality of chips to the carrier.

In described examples, a microelectronic device includes a microelectronic die with a die attach surface. The microelectronic device further includes a nanoparticle layer coupled to the die attach surface. The nanoparticle layer may be in direct contact with the die attach surface, or may be coupled to the die attach surface through an intermediate layer, such as an adhesion layer or a contact metal layer. The nanoparticle layer includes nanoparticles having adjacent nanoparticles adhered to each other. The microelectronic die is attached to a package substrate by a die attach material. The die attach material extends into the nanoparticle layer and contacts at least a portion of the nanoparticles.