Certain aspects of the present disclosure generally relate to an embedded trace substrate (ETS) with one or more passive components embedded therein. Such an ETS may provide shorter routing, smaller loop area, and lower parasitics between a semiconductor die and a land-side passive component embedded in the ETS. One example embedded trace substrate generally includes a core, a first insulating material disposed above the core and having a first metal pattern embedded therein, a second insulating material disposed below the core and having a second metal pattern embedded therein, and one or more passive components embedded in the core.

A method of forming a semiconductor device includes: depositing a first conductive plate and a second conductive plate adjacent to the first conductive plate; depositing a first insulating plate on the first conductive plate and the second conductive plate; depositing a third conductive plate on the first insulating plate; depositing a second insulating plate on the third conductive plate; forming a fourth conductive plate on the second insulating plate; forming a first conductive via penetrating the fourth conductive plate, the second insulating plate, the first insulating plate, and the first conductive plate; and forming a second conductive via penetrating the second insulating plate, the third conductive plate, the first insulating plate, and the second conductive plate.

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.

A chip part includes a substrate, an element formed on the substrate, and an electrode formed on the substrate. A recess and/or projection expressing information related to the element is formed at a peripheral edge portion of the substrate.

A first semiconductor structure including a first bonding oxide layer having a first metallic structure embedded therein and a second semiconductor structure including a second bonding oxide layer having second metallic structure embedded therein are provided. A high-k dielectric material is formed on a surface of the first metallic structure. A nitride surface treatment process is performed to provide a nitrided surface layer to each structure. The nitrided surface layer includes nitridized oxide regions located in an upper portion of the bonding oxide layers and either a nitridized high-k dielectric material located in at least an upper portion of the high k dielectric material or a nitridized metallic region located in an upper portion of the second metallic structure. The nitrogen within the nitridized metallic region is then selectively removed to restore the upper portion of the second metallic structure to its original composition. Bonding is then performed.

A metal capacitor provided includes a first metal layer and a second metal layer disposed above a substrate. The first metal layer includes a first electrode sheet and a second electrode sheet, and the second metal layer includes a third electrode sheet and a fourth electrode sheet. The first electrode sheet and the second electrode sheet collectively form a first coplanar capacitor. The third electrode sheet and the fourth electrode sheet collectively form a second coplanar capacitor. At least a portion of the fourth electrode sheet is arranged above the first electrode sheet, and the first electrode sheet and the fourth electrode sheet collectively form a first vertical capacitor. At least a portion of the third electrode sheet is arranged above the second electrode sheet, and the second electrode sheet and the third electrode sheet collectively form a second vertical capacitor.

An integrated circuit includes a trench power rail to reduce resistance in a power rail or avoid an increase in resistance of a power rail as a result of the metal tracks being reduced in size as the technology node size is reduced. The trench power rail is formed in isolation regions between cell circuits. A cell isolation trench in the isolation region provides additional volume in which to dispose additional metal material for forming the trench power rail to increase its cross-sectional area. The trench power rail extends through a via layer to a metal layer, including signal interconnects. The trench power rail extends in a width direction out of the cell isolation trench in the via layer to couple to trench contacts of the adjacent cell circuits without vertical interconnect accesses (vias). A high-K dielectric layer can selectively isolate the trench power rail from the cell circuits.

A structural body that includes: a substrate; a plurality of fibrous materials, each of the plurality of fibrous material including a fibrous core material and a covering layer that covers the fibrous core material such that an exposed portion of the fibrous core material is formed at an end portion thereof; and an adhesive layer that bonds the substrate and the end portion of each of the plurality of fibrous materials to each other such that a boundary between the covering layer and the exposed portion is located inside the adhesive layer.

A metal-insulator-metal (MIM) capacitor includes a first group of metal contacts disposed on a first region of an isolation layer spaced apart from each other in a first direction, a second group of metal contacts disposed on a second region of the isolation layer spaced apart from each other in the first direction, a dielectric layer disposed between the first group of metal contacts and the second group of metal contacts, a first metal electrode disposed to contact the top surfaces of the first group of metal contacts, and a second metal electrode disposed to contact the top surfaces of the second group of metal contacts.

A power chip includes: a first power switch, formed in a wafer region and having a first and a second metal electrodes; a second power switch, formed in the wafer region and having a third and a fourth metal electrodes, wherein the first and second power switches respectively constitute an upper bridge arm and a lower bridge arm of a bridge circuit, and the first and second power switches are alternately arranged; and a metal region, at least including a first metal layer and a second metal layer that are stacked, each metal layer including a first to a third electrodes, and electrodes with the same voltage potential in the metal layers are electrically coupled.