A method of making microstructures having re-entrant or doubly re-entrant topology includes forming a mold defining the negative surface features of the re-entrant or doubly re-entrant topology that is to be formed. In one embodiment, a soft or flowable material is formed on a first substrate and the mold is contacted with the same to form a solid, now positive surface having the re-entrant or doubly re-entrant topology. The mold is then released from the first substrate. The microstructures are secured to a second, different substrate, and the first substrate is removed. Any residual microstructure material located between adjacent microstructures may be removed to form the separate microstructures on the second substrate. The second substrate may be thin and flexible any manipulated into useful or desired shapes having the microstructures on one side thereof.

An integrated semiconductor device includes: a MEMS structure; an ASIC electronic circuit; and conductive interconnection structures electrically coupling the MEMS structure to the ASIC electronic circuit. The MEMS structure and the ASIC electronic circuit are integrated starting from a same substrate including semiconductor material; wherein the MEMS structure is formed at a first surface of the substrate, and the ASIC electronic circuit is formed at a second surface of the substrate, vertically opposite to the first surface in a direction transverse to a horizontal plane of extension of the first surface and of the second surface.

The present disclosure relates to a packaging process to enhance performance of a wafer-level package. The disclosed package includes multiple mold compounds, a multilayer redistribution structure, and a thinned die with a device layer and die bumps underneath the device layer. The multilayer redistribution structure includes package contacts at a bottom of the multilayer redistribution structure and redistribution interconnects connecting the die bumps to the package contacts. A first mold compound resides around the thinned die to encapsulate sidewalls of the thinned die, and extends beyond a top surface of the thinned die to define an opening over the thinned die. A second mold compound resides between the multilayer redistribution structure and the first mold compound to encapsulate a bottom surface of the device layer and each die bump. A third mold compound fills the opening and is in contact with the top surface of the thinned die.

A method of forming at least one Micro-Electro-Mechanical System (MEMS) includes forming a beam structure and an electrode on an insulator layer, remote from the beam structure. The method further includes forming at least one sacrificial layer over the beam structure, and remote from the electrode. The method further includes forming a lid structure over the at least one sacrificial layer and the electrode. The method further includes providing simultaneously a vent hole through the lid structure to expose the sacrificial layer and to form a partial via over the electrode. The method further includes venting the sacrificial layer to form a cavity. The method further includes sealing the vent hole with material. The method further includes forming a final via in the lid structure to the electrode, through the partial via.

A thin-film package includes: a substrate; a wiring layer disposed on the substrate; a microelectromechanical systems (MEMS) element disposed on a surface of the substrate; a partition wall disposed on the substrate to surround the MEMS element, and formed of a polymer material; a cap forming a cavity with the substrate and the partition wall; and an external connection electrode connected to the wiring layer. The external connection electrode includes at least one inclined portion disposed on at least one inclined surface formed on any one or any combination of any two or more of the substrate, the partition wall, and the cap.

A semiconductor package structure includes an electronic device having an exposed region adjacent to a first surface, a dam surrounding the exposed region of the semiconductor die and disposed on the first surface, the dam having a top surface away from the first surface, an encapsulant encapsulating the first surface of the electronic device, exposing the exposed region of the electronic device. A surface of the dam is retracted from a top surface of the encapsulant. A method for manufacturing the semiconductor package structure is also provided.

A method for producing a micromechanical element includes producing a micromechanical structure, the micromechanical structure having: a functional layer for a micromechanical element, a sacrifical layer at least partly surrounding the functional layer, and a closure cap on the sacrifical layer. The method further includes applying a cover layer on the micromechanical structure. The method further includes producing a grid structure in the cover layer. The method further includes producing a cavity below the grid structure, as access to the sacrifical layer. The method further includes at least partly removing the sacrifical layer. The method further includes applying a closure layer at least on the grid structure of the cover layer for the purpose of closing the access to the cavity.

Micro-Electro-Mechanical System (MEMS) structures, methods of manufacture and design structures are disclosed. The method includes forming at least one Micro-Electro-Mechanical System (MEMS) cavity. The method for forming the cavity further includes forming at least one first vent hole of a first dimension which is sized to avoid or minimize material deposition on a beam structure during sealing processes. The method for forming the cavity further includes forming at least one second vent hole of a second dimension, larger than the first dimension.

A method for forming a MEMS device may include performing a silicon-on-nothing process to form a cavity in a monocrystalline silicon substrate at a first depth relative to a top surface of the monocrystalline silicon substrate; forming, in an electrically conductive electrode region of the monocrystalline silicon substrate, an electrically insulated region extending to a second depth that is less than the first depth relative to the top surface of the monocrystalline silicon substrate; and etching the monocrystalline silicon substrate to expose a gap between a first electrode and a second electrode, wherein the second electrode is separated from the first electrode, within a first depth region, by a first distance defined by the electrically insulated region and the gap, and wherein the second electrode is separated from the first electrode, within a second depth region, by a second distance defined by the gap.

A packaged micro-electro-mechanical system (MEMS) device (100) comprises a circuitry chip (101) attached to the pad (110) of a substrate with leads (111), and a MEMS (150) vertically attached to the chip surface by a layer (140) of low modulus silicone compound. On the chip surface, the MEMS device is surrounded by a polyimide ring (130) with a surface phobic to silicone compounds. A dome-shaped glob (160) of cured low modulus silicone material covers the MEMS and the MEMS terminal bonding wire spans (180); the glob is restricted to the chip surface area inside the polyimide ring and has a surface non-adhesive to epoxy-based molding compounds. A package (190) of polymeric molding compound encapsulates the vertical assembly of the glob embedding the MEMS, the circuitry chip, and portions of the substrate; the molding compound is non-adhering to the glob surface yet adhering to all other surfaces.