Various embodiments of the present disclosure are directed towards a memory device including a first bottom electrode layer over a substrate. A ferroelectric switching layer is disposed over the first bottom electrode layer. A first top electrode layer is disposed over the ferroelectric switching layer. A second bottom electrode layer is disposed between the first bottom electrode layer and the ferroelectric switching layer. The second bottom electrode layer is less susceptible to oxidation than the first bottom electrode layer.

A capacitor is made using a wafer, and includes structural elevation portions to allow an electrode layer in the capacitor to be extended along surface profiles of the structural elevation portions to thereby increase its extension length, so as to reduce capacitor area, simplify capacitor manufacturing process and reduce manufacturing cost.

The present invention relates to a semiconductor device having a capacitor and a method for fabricating the same. A semiconductor device may comprise: a lower electrode; a supporter supporting an outer wall of the lower electrode; a dielectric layer formed over the lower electrode and the supporter; an upper electrode formed on the dielectric layer; and a dielectric booster layer disposed between the lower electrode and the dielectric layer, and selectively formed on a surface of the lower electrode.

A capacitor structure that includes a silicon substrate having a trench structure formed therein; a dielectric disposed over a surface of the trench structure, conformal to the surface of the trench structure; and a filling layer disposed over the dielectric layer and into the trench structure, the filling layer including a conductive layer and a polymer layer.

An embodiment of the present disclosure provides a MIM capacitor by High-k dielectric and method for fabricating the same to prevent formation of oxygen-based interface films between a lower electrode and a dielectric layer, and between an upper electrode and a dielectric layer by stacking a first film formed of metal between the dielectric layer formed of a High-k material having a high dielectric constant and the lower electrode formed of metal, and a second film formed of metal between the dielectric layer and the upper electrode.

An integrated electronic circuit including: a dielectric body delimited by a front surface; A top conductive region of an integrated electronic circuit extend within a dielectric body having a front surface. A passivation structure including a bottom portion and a top portion laterally delimits an opening. The bottom portion extends on the front surface, and the top portion extends on the bottom portion. A field plate includes an internal portion and an external portion. The internal portion is located within the opening and extends on the top portion of the passivation structure. The external portion extends laterally with respect to the top portion of the passivation structure and contacts at a bottom one of: the dielectric body or the bottom portion of the passivation structure. The opening and the external portion are arranged on opposite sides of the top portion of the passivation structure.

A semiconductor device is provided that includes a substrate 10 with first and second opposing main surfaces, a circuit layer disposed on the first main surface, and a first resin body on a surface of the circuit layer opposite from the substrate. The circuit layer includes first and second electrode layers on a side of the semiconductor substrate, a dielectric layer disposed between the electrode layers, a first outer electrode electrically connected to the first electrode layer and extended to the surface of the circuit layer, and a second outer electrode electrically connected to the second electrode layer and extended to the surface of the circuit layer. The first resin body is between the first and second outer electrodes in a plan view, and in sectional view, a tip end of the first resin body is positioned higher than tip ends of the first and second outer electrodes.

A method for fabricating a semiconductor device includes forming an upper structure in which a bottom electrode, a dielectric layer, a top electrode and a plasma protection layer are sequentially stacked on a lower structure, exposing the upper structure to a plasma treatment, and exposing the plasma-treated upper structure and the lower structure to a hydrogen passivation process.

Embodiments of the present invention are directed to a back-end-of-line (BEOL) compatible metal-insulator-metal on-chip decoupling capacitor (MIMCAP). This BEOL compatible process includes a thermal treatment for inducing an amorphous-to-cubic phase change in the insulating layer of the MIM stack prior to forming the top electrode. In a non-limiting embodiment of the invention, a bottom electrode layer is formed, and an insulator layer is formed on a surface of the bottom electrode layer. The insulator layer can include an amorphous dielectric material. The insulator layer is thermally treated such that the amorphous dielectric material undergoes a cubic phase transition, thereby forming a cubic phase dielectric material. A top electrode layer is formed on a surface of the cubic phase dielectric material of the insulator layer.

The present disclosure relates to a semiconductor device and a manufacturing method, and more particularly to a MIM dual capacitor structure with an increased capacitance per unit area in a semiconductor structure. Without using additional mask layers, a second parallel plate capacitor can be formed over a first parallel plate capacitor, and both capacitors share a common capacitor plate. The two parallel plate capacitors can be connected in parallel to increase the capacitance per unit area.