A microelectronic device includes a semiconductor substrate and a high voltage isolation capacitor over the substrate. The capacitor includes a bottom capacitor plate over the substrate. Dielectric layers are formed above the bottom capacitor plate, including a top dielectric layer. A high dielectric layer on the top dielectric layer includes at least a first sublayer having a first dielectric constant that is higher than a dielectric constant of the top dielectric layer. A top capacitor plate is formed on the high dielectric layer over the bottom capacitor plate. An electric field abatement structure surrounds the top capacitor plate. The electric field abatement structure includes a shelf of the high dielectric layer extending outward from a lower corner of the bottom capacitor plate at least 14 microns, and an isolation break in the high dielectric layer past the shelf, in which the first sublayer is removed from the isolation break.

Embodiments include semiconductor packages. A semiconductor package includes a plurality of build-up layers and a plurality of conductive layers in the build-up layers. The conductive layers include a first conductive layer and a second conductive layer. The first conductive layer is over the second conductive layer and build-up layers, where a first via couples the first and second conductive layers. The semiconductor package also includes a thin film capacitor (TFC) in the build-up layers, where a second via couples the TFC to the first conductive layer, and the second via has a thickness less than a thickness of the first via. The first conductive layer may be first level interconnects. The build-up layers may be dielectrics. The TFC may include a first electrode, a second electrode, and a dielectric. The first electrode may be over the second electrode, and the dielectric may be between the first and second electrodes.

A trench capacitor manufacturing method is provided. The method includes forming a deep trench in a wafer, forming a trench capacitor structure including a plurality of dielectric films and a plurality of conductive layers in the deep trench; determining if the wafer has a tensile stress based on the forming of the trench capacitor structure; performing a high temperature heat treatment to the trench capacitor structure to change a form of the wafer to a direction that offsets the tensile stress; forming an inter-layer insulating film on the trench capacitor structure; and forming a metal interconnect on the inter-layer insulating film.

A semiconductor structure comprises a semiconductor substrate, a first trench capacitor, and a second trench capacitor. The substrate has first trenches arranged in a first arrangement direction with each first trench extending in a first extension direction and second trenches arranged in a second arrangement direction with each second trench extending in a second extension direction. The first trench capacitor includes first capacitor segments disposed inside the first trenches. The second trench capacitor includes second capacitor segments disposed inside the second trenches. One first capacitor segment of the first capacitor segments has an extending length different from that of another first capacitor segment of the first capacitor segments, and one second capacitor segment of the second capacitor segments has an extending length different from that of another second capacitor segment of the second capacitor segments.

The present application discloses a semiconductor device, an electronic system and an electrostatic discharge (ESD) protection method for a semiconductor device thereof. The semiconductor device includes a substrate, an operation solder structure disposed on a first surface of the substrate for receiving an operation signal, a detection solder structure disposed on the first surface of the substrate for receiving a chip connection signal, and a semiconductor chip disposed on a second surface of the substrate. The semiconductor chip includes an operation electrical contact coupled to the operation solder structure, a detection electrical contact coupled to the detection solder structure, an ESD protection unit coupled to the operation electrical contact, and a logic circuit coupled to the detection electrical contact for adjusting capacitance of the ESD protection unit according to the chip connection signal.

A semiconductor package includes a plurality of inorganic dielectric layers including a plurality of metal interconnect layers formed therein and a plurality of first contact pads, a plurality of organic dielectric layers disposed on and electrically connected to the plurality of inorganic dielectric layers and including a plurality of metal redistribution layers formed therein, wherein the plurality of metal redistribution layers are physically connected to the plurality of first contact pads, and a semiconductor die mounted on the plurality of organic dielectric layers and electrically connected to the plurality of metal redistribution layers through the plurality of metal interconnect layers.

Various embodiments of the present application are directed towards a method for forming a metal-insulator-metal (MIM) capacitor comprising an enhanced interfacial layer to reduce breakdown failure. In some embodiments, a bottom electrode layer is deposited over a substrate. A native oxide layer is formed on a top surface of the bottom electrode layer and has a first adhesion strength with the top surface. A plasma treatment process is performed to replace the native oxide layer with an interfacial layer. The interfacial layer is conductive and has a second adhesion strength with the top surface of the bottom electrode layer, and the second adhesion strength is greater than the first adhesion strength. An insulator layer is deposited on the interfacial layer. A top electrode layer is deposited on the insulator layer. The top and bottom electrode layers, the insulator layer, and the interfacial layer are patterned to form a MIM capacitor.

Isolators for high frequency signals transmitted between two circuits configured to operate at different voltage domains are provided. The isolators may include resonators capable of operating at high frequencies with high bandwidth, high transfer efficiency, high isolation rating, and a small substrate footprint. In some embodiments, the isolators may operate at a frequency not less than 30 GHz, not less than 60 GHz, or between 20 GHz and 200 GHz, including any value or range of values within such range. The isolators may include isolator components galvanically isolated from and capacitively coupled to each other. The sizes and shapes of the isolator components may be configured to control the values of equivalent inductances and capacitances of the isolators to facilitate resonance in operation. The isolators are compatible to different fabrication processes including, for example, micro-fabrication and PCB manufacture processes.

A semiconductor structure includes an interposer substrate having an upper surface, a lower surface opposite to the upper surface, and a device region. A first redistribution layer is formed on the upper surface of the interposer substrate. A guard ring is formed in the interposer substrate and surrounds the device region. At least a through-silicon via (TSV) is formed in the interposer substrate. An end of the guard ring and an end of the TSV that are near the upper surface of the interposer substrate are flush with each other, and are electrically connected to the first redistribution layer.

Various embodiments may provide a semiconductor package. The semiconductor package may include a semiconductor chip, a first mold compound layer at least partially covering the semiconductor chip, and a redistribution layer over the first mold compound layer, the redistribution layer including one or more electrically conductive lines in electrical connection with the semiconductor chip. The semiconductor package may additionally include a second mold compound layer over the redistribution layer, and an antenna array over the second mold compound layer, the antenna array configured to be coupled to the one or more electrically conductive lines.