Packaged semiconductor components having substantially rigid support member are disclosed. The packages can include a semiconductor die and a support member proximate to the semiconductor die. The support member is at least substantially rigid. The packages can further include an adhesive between the support member and the semiconductor die and adhesively attaching the support member to the semiconductor die. The packages can also include a substrate carrying the semiconductor die and the support member attached to the semiconductor die.

Packaged semiconductor components having substantially rigid support member are disclosed. The packages can include a semiconductor die and a support member proximate to the semiconductor die. The support member is at least substantially rigid. The packages can further include an adhesive between the support member and the semiconductor die and adhesively attaching the support member to the semiconductor die. The packages can also include a substrate carrying the semiconductor die and the support member attached to the semiconductor die.

A stacked mounting structure and a method of manufacturing stacked mounting structure are provided. The stacked mounting structure includes a plurality of members provided with a mounting area which is necessary for installing and operating components to be mounted on at least one principal surface, and an area for connections for signal transfer for operating the components to be mounted, and an electroconductive member which is disposed on the area for connections between the mutually facing members, and a cross section of the electroconductive member is same as or smaller than the area for connections, and an end portion of the electroconductive member is extended from a principal surface of one member up to a principal surface of the other member, and a height of the electroconductive member regulates a distance of the mounting area.

An electronic sub-assembly (36) comprising at least one electronic component (14) embedded in a sequence of layers, wherein the electronic component (14) is arranged in a recess of an electrically conductive central layer (16) and directly adjoins a resin layer (12, 20) on each side.

An electronic sub-assembly (36) comprising at least one electronic component (14) embedded in a sequence of layers, wherein the electronic component (14) is arranged in a recess of an electrically conductive central layer (16) and directly adjoins a resin layer (12, 20) on each side.

Capacitive coupling of integrated circuit die components and other conductive areas is provided. Each component to be coupled has a surface that includes at least one conductive area, such as a metal pad or plate. An ultrathin layer of dielectric is formed on at least one surface to be coupled. When the two components, e.g., one from each die, are permanently contacted together, the ultrathin layer of dielectric remains between the two surfaces, forming a capacitor or capacitive interface between the conductive areas of each respective component. The ultrathin layer of dielectric may be composed of multiple layers of various dielectrics, but in one implementation, the overall thickness is less than approximately 50 nanometers. The capacitance per unit area of the capacitive interface formed depends on the particular dielectric constants of the dielectric materials employed in the ultrathin layer and their respective thicknesses. Electrical and grounding connections can be made at the edge of the coupled stack.

Microelectronic devices and method of forming a plurality of microelectronic devices on a semiconductor workpiece are disclosed herein. One such method includes placing a plurality of first interconnect elements on a side of a semiconductor workpiece, forming a layer on the side of the workpiece, reshaping the first interconnect elements by heating the first interconnect elements, and coupling a first portion of a plurality of individual second interconnect elements to corresponding first interconnect elements with a second portion of the individual second interconnect elements exposed.

The present invention relates to a bonding method for connecting a first wafer and a second wafer, wherein firstly a first adhesive layer is deposited onto a surface of the first wafer. Furthermore, a second adhesive layer is deposited onto the first adhesive layer, and the two adhesive layers are structured by way of selective removal of both adhesive layers in at least one predefined region of the first wafer, Moreover, the first wafer is connected to the second wafer by way of pressing a surface of the second wafer onto the second adhesive layer, wherein the second adhesive layer is more flowable that the first adhesive layer on connecting the first wafer to the second wafer.

The present invention relates to a bonding method for connecting a first wafer and a second wafer, wherein firstly a first adhesive layer is deposited onto a surface of the first wafer. Furthermore, a second adhesive layer is deposited onto the first adhesive layer, and the two adhesive layers are structured by way of selective removal of both adhesive layers in at least one predefined region of the first wafer, Moreover, the first wafer is connected to the second wafer by way of pressing a surface of the second wafer onto the second adhesive layer, wherein the second adhesive layer is more flowable that the first adhesive layer on connecting the first wafer to the second wafer.

Microelectronic devices and method of forming a plurality of microelectronic devices on a semiconductor workpiece are disclosed herein. One such method includes placing a plurality of first interconnect elements on a side of a semiconductor workpiece, forming a layer on the side of the workpiece, reshaping the first interconnect elements by heating the first interconnect elements, and coupling a first portion of a plurality of individual second interconnect elements to corresponding first interconnect elements with a second portion of the individual second interconnect elements exposed.