A non-volatile memory device with a programmable leakage can be formed employing a trench capacitor. After formation of a deep trench, a metal-insulator-metal stack is formed on surfaces of the deep trench employing a dielectric material that develops leakage path filaments upon application of a programming bias voltage. A set of programming transistors and a leakage readout device can be formed to program, and to read, the state of the leakage level. The non-volatile memory device can be formed concurrently with formation of a dynamic random access memory (DRAM) device by forming a plurality of deep trenches, depositing a stack of an outer metal layer and a node dielectric layer, patterning the node dielectric layer to provide a first node dielectric for each non-volatile memory device that is thinner than a second node dielectric for each DRAM device, and forming an inner metal layer.

A semiconductor arrangement includes an active region including a semiconductor device. The semiconductor arrangement includes a capacitor having a first electrode layer, a second electrode layer, and an insulating layer between the first electrode layer and the second electrode layer. At least three dielectric layers are between a bottom surface of the capacitor and the active region.

Methods of forming passive elements under a device layer are described. Those methods and structures may include forming at least one passive structure, such as a capacitor and a resistor structure, in a substrate, wherein the passive structures are vertically disposed within the substrate. An insulator layer is formed on a top surface of the passive structure, a device layer is formed on the insulator layer, and a contact is formed to couple a device disposed in the device layer to the at least one passive structure.

A semiconductor device includes a plurality of memory cells being disposed in a matrix in a memory cell array area, each of the memory cells includes a capacitive element including a cell plate electrode, a capacitive insulating film, and a storage node electrode, and a switch transistor coupled between the storage node electrode and a bit line and being controlled based on a potential of a word line, a peripheral circuit disposed in a peripheral circuit area adjacent to the memory cell array area, and a signal line formed at a boundary between the memory cell array area and the peripheral circuit area. The capacitive element has a cylinder shape. The storage node electrode is formed on inner wall of a hole which penetrates through a first insulating film layer and a second insulating film layer.

A device structure according to the present disclosure includes a metal-insulator-metal (MIM) stack that includes a plurality of conductor plate layers interleaved by a plurality of insulator layers. The MIM stack includes a first region and a second region and the first region and the second region overlaps in a third region. The MIM stack further includes a first via passing through the first region and electrically coupled to a first subset of the plurality of conductor plate layers, a second via passing through the second region and electrically coupled to a second subset of the plurality of conductor plate layers, and a ground via passing through the third region and electrically coupled to a third subset of the plurality of conductor plate layers.

The present disclosure provides a method for manufacturing a semiconductor structure and a semiconductor structure. The method for manufacturing a semiconductor structure includes: forming a plurality of capacitor holes on a substrate, and exposing a part of the substrate on bottoms of the capacitor holes; forming a bottom electrode layer on surfaces of the capacitor holes; forming, on a surface of the bottom electrode layer, a dielectric layer continuously covering the surface of the bottom electrode layer; forming a first top electrode layer to continuously cover a surface of the dielectric layer by a first film forming process; by a second film forming process, forming, in a circumferential direction of the capacitor holes, a second top electrode layer continuously covering a surface of the first top electrode layer, and forming, in an axial direction of the capacitor holes.

High density capacitor structures based on an array of semiconductor nanorods are provided. The high density capacitor structure can be a plurality of capacitors in which each of the semiconductor nanorods serves as a bottom electrode for one of the plurality of capacitors, or a large-area metal-insulator-metal (MIM) capacitor in which the semiconductor nanorods serve as a support structure for a bottom electrode of the MIM capacitor subsequently formed.

In some embodiments, a system may include an integrated circuit. The integrated circuit may include a substrate including a first surface, a second surface substantially opposite of the first surface, and a first set of electrical conductors coupled to the first surface. The first set of electrical conductors may function to electrically connect the integrated circuit to a circuit board. The integrated circuit may include a semiconductor die coupled to the second surface of the substrate using a second set of electrical conductors. The integrated circuit may include a passive device dimensioned to be integrated with the integrated circuit. The passive device may be positioned between the second surface and at least one of the first set of electrical conductors. The die may be electrically connected to a second side of the passive device. A first side of the passive device may be available to be electrically connected to a second device.

A method of forming conductive vias comprises forming at least three parallel line constructions elevationally over a substrate. The line constructions individually comprise a dielectric top and dielectric sidewalls. A conductive line is formed elevationally over and angles relative to the line constructions. The conductive line comprises a longitudinally continuous portion and a plurality of conductive material extensions that individually extend elevationally inward between immediately adjacent of the line constructions. Etching is conducted elevationally through the longitudinally continuous portion and partially elevationally into the extensions at spaced locations along the conductive line to break-up the longitudinally continuous portion to form individual conductive vias extending elevationally between immediately adjacent of the line constructions. Methods of forming a memory array are also disclosed. Arrays of conductive vias independent of method of manufacture are also disclosed.

The invention relates to a capacitor structure (2) comprising a silicon substrate (4) with first and second sides (6, 8), a double double Metal Insulator Metal trench capacitor (10) including a basis electrode (12), an insulator layer (16, 20), a second and a third conductive layers (18, 22); and comprising a second pad (26) and a fourth pad (30) coupled to the basis electrode (12), a first pad (24) and a third pad (28) coupled together, the first pad (24) being located on the same substrate side than the second pad (26), the third pad (28) being located on the same substrate side than the fourth pad (30), the third pad (28) being coupled to the second conductive layer (18), said second conductive layer (18) being flush with or protruding from the opposite second side (8).