A conductive connecting member formed on a bonded face of an electrode terminal of a semiconductor or an electrode terminal of a circuit board, the conductive connecting member comprising a porous body formed in such manner that a conductive paste containing metal fine particles (P) having mean primary particle diameter from 10 to 500 nm and an organic solvent (S), or a conductive paste containing the metal fine particles (P) and an organic dispersion medium (D) comprising the organic solvent (S) and an organic binder (R) is heating-treated so as for the metal fine particles (P) to be bonded, the porous body being formed by bonded metal fine particles (P) having mean primary particle diameter from 10 to 500 nm, a porosity thereof being from 5 to 35 volume %, and mean pore diameter being from 1 to 200 nm.

The present invention includes: preparing a semiconductor substrate having a first main surface and a second main surface that is located on an opposite side of the first main surface; forming a first electrode on the first main surface; forming a solder-bonding metal film (a first solder-bonding metal film) on the first electrode; forming a sacrificial film on the first solder-bonding metal film; grinding the second main surface after forming the sacrificial film; performing heat treatment after the grinding (forming an element structure on the third main surface side); removing the sacrificial film after the performing heat treatment; and solder-bonding the first solder-bonding metal film and a first external electrode.

A pre-soldered circuit carrier includes a carrier having a metal die attach surface, a plated solder region on the metal die attach surface, wherein a maximum thickness of the plated solder region is at most 50 ?m, the plated solder region has a lower melting point than the first bond pad, and the plated solder region forms one or more intermetallic phases with the die attach surface at a soldering temperature that is above the melting point of the plated solder region.

A pre-soldered circuit carrier includes a carrier having a metal die attach surface, a plated solder region on the metal die attach surface, wherein a maximum thickness of the plated solder region is at most 50 ?m, the plated solder region has a lower melting point than the first bond pad, and the plated solder region forms one or more intermetallic phases with the die attach surface at a soldering temperature that is above the melting point of the plated solder region.

According to various embodiments, a method for manufacturing a semiconductor device may include providing a semiconductor workpiece including a device region at a first side of the semiconductor workpiece, wherein a mechanical stability of the semiconductor workpiece is insufficient to resist at least one back end process without damage, and depositing at least one conductive layer over a second side of the semiconductor workpiece opposite the first side of the semiconductor workpiece, wherein the at least one conductive layer increases the mechanical stability of the semiconductor workpiece to be sufficient to resist the at least one back end process without damage.

A semiconductor device and method of manufacturing is provided, whereby a support structure is utilized to provide additional support for a conductive element in order to eliminate or reduce the formation of a defective surface such that the conductive element may be formed to have a thinner structure without suffering deleterious structures.

In described examples, a hermetic package of a microelectromechanical system (MEMS) structure includes a substrate having a surface with a MEMS structure of a first height. The substrate is hermetically sealed to a cap forming a cavity over the MEMS structure. The cap is attached to the substrate surface by a vertical stack of metal layers adhering to the substrate surface and to the cap. The stack has a continuous outline surrounding the MEMS structure while spaced from the MEMS structure by a distance. The stack has: a first bottom metal seed film adhering to the substrate and a second bottom metal seed film adhering to the first bottom metal seed film; and a first top metal seed film adhering to the cap and a second top metal seed film adhering to the first top metal seed film.

In described examples, a hermetic package of a microelectromechanical system (MEMS) structure includes a substrate having a surface with a MEMS structure of a first height. The substrate is hermetically sealed to a cap forming a cavity over the MEMS structure. The cap is attached to the substrate surface by a vertical stack of metal layers adhering to the substrate surface and to the cap. The stack has a continuous outline surrounding the MEMS structure while spaced from the MEMS structure by a distance. The stack has: a first bottom metal seed film adhering to the substrate and a second bottom metal seed film adhering to the first bottom metal seed film; and a first top metal seed film adhering to the cap and a second top metal seed film adhering to the first top metal seed film.

A semiconductor chip includes a semiconductor body having a lower side with a lower chip metallization applied thereto. A first contact metallization layer is produced on the lower chip metallization. A second contact metallization layer is produced on a metal surface of a substrate. The semiconductor chip and the substrate are pressed onto one another for a pressing time so that the first and second contact metallization layers bear directly and extensively on one another. During the pressing time, the first contact metallization layer is kept continuously at temperatures which are lower than the melting temperature of the first contact metallization layer. The second contact metallization layer is kept continuously at temperatures which are lower than the melting temperature of the second contact metallization layer during the pressing time. After the pressing together, the first and second contact metallization layers have a total thickness less than 1000 nm.

A semiconductor chip includes a semiconductor body having a lower side with a lower chip metallization applied thereto. A first contact metallization layer is produced on the lower chip metallization. A second contact metallization layer is produced on a metal surface of a substrate. The semiconductor chip and the substrate are pressed onto one another for a pressing time so that the first and second contact metallization layers bear directly and extensively on one another. During the pressing time, the first contact metallization layer is kept continuously at temperatures which are lower than the melting temperature of the first contact metallization layer. The second contact metallization layer is kept continuously at temperatures which are lower than the melting temperature of the second contact metallization layer during the pressing time. After the pressing together, the first and second contact metallization layers have a total thickness less than 1000 nm.