Embodiments of a three-dimensional capacitor for a memory device and fabrication methods are disclosed. The method includes forming, on a first side of a first substrate, a peripheral circuitry having a plurality of peripheral devices, a first interconnect layer, a deep well and a first capacitor electrode. The method also includes forming, on a second substrate, a memory array having a plurality of memory cells and a second interconnect layer, and bonding the first interconnect layer of the peripheral circuitry with the second interconnect layer of the memory array. The method further includes forming, on a second side of the first substrate, one or more trenches inside the deep well, disposing a capacitor dielectric layer on sidewalls of the one or more trenches, and forming capacitor contacts on sidewalls of the capacitor dielectric layer inside the one or more trenches.

The present description concerns a capacitor manufacturing method, including the successive steps of: a) forming a stack including, in the order from the upper surface of a substrate, a first conductive layer made of aluminum or an aluminum-based alloy, a first electrode, a first dielectric layer, and a second electrode; b) etching, by chemical plasma etching, an upper portion of the stack, said chemical plasma etching being interrupted before the upper surface of the first conductive layer; and c) etching, by physical plasma etching, a lower portion of the stack, said physical plasma etching being interrupted on the upper surface of the first conductive layer.

Some embodiments include a method in which an assembly is formed to have a first silicon-dioxide-containing-material and a second silicon-dioxide-containing-material. The first silicon-dioxide-containing-material has a higher concentration of dopant therein than does the second silicon-dioxide-containing-material. The first silicon-dioxide-containing-material is selectively removed relative to the second silicon-dioxide-containing-material using a mixture which includes hydrofluoric acid, a second acid and an organic solvent. The organic solvent may include at least one ester and/or at least one ether. The second acid may have a pKa of less than about 5.

An integrated circuit structure includes a first conductive plate, a second conductive plate, a plurality of conductive lines, and a plurality of conductive vias. The first conductive plate is disposed in a first layer on a semiconductor substrate. The second conductive plate is disposed in a second layer on the semiconductor substrate. The plurality of conductive lines are disposed in the first layer for surrounding the first conductive plate. The plurality of conductive vias are arranged to couple the plurality of conductive lines to the second conductive plate. The second layer is different from the first layer, and the first conductive plate is physically separated from the second conductive plate, the plurality of conductive lines, and the plurality of conductive vias.

Present disclosure provide a capacitor includes: a semiconductor substrate; a laminated structure including n conductive layers and m dielectric layer(s), the i-th conductive layer being provided with at least one i-th isolation trench, the (i+1)-th conductive layer being provided above the i-th conductive layer and in the i-th isolation trench, isolation trenches in odd-numbered and even-numbered conductive layers having a first and a second overlap region in a vertical direction respectively, and the first overlap region not overlapping the second overlap region, where m, n, and i are positive integers, n≥2, and 1≤i≤n−1; at least one first external electrode electrically connected to all odd-numbered conductive layer(s) through a first conductive via structure in the second overlap region; and at least one second external electrode electrically connected to all even-numbered conductive layer(s) through a second conductive via structure in the first overlap region.

A capacitor structure may include a lower electrode on a substrate, a dielectric layer on the substrate, and an upper electrode on the dielectric layer. The lower electrode may include a metal nitride having a chemical formula of M.sup.1N.sub.y (M.sup.1 is a first metal, and y is a positive real number). The dielectric layer may include a metal oxide and nitrogen (N), the metal oxide having a chemical formula of M.sup.2O.sub.x (M.sup.2 is a second metal, and x is a positive real number). A maximum value of a detection amount of nitrogen (N) in the dielectric layer may be greater than a maximum value of a detection amount of nitrogen (N) in the lower electrode.

The present disclosure relates to a memory device, and more particularly, to a memory device including a substrate, a plurality of vertical structures disposed on the substrate and including insulation layers and lower electrodes, which are alternately laminated with each other, wherein the vertical structures are aligned in a first direction parallel to a top surface of the substrate and a second direction crossing the first direction, an upper electrode disposed on a top surface and side surfaces of each of the vertical structures, and a first dielectric layer disposed between the upper electrode and the vertical structures to cover the top surface and the side surfaces of each of the vertical structures. Here, the first dielectric layer includes a ferroelectric material.

A metal-insulator-metal (MIM) capacitor module includes an outer electrode, an insulator, an inner electrode, an outer electrode extension structure, an inner electrode contact element, and an outer electrode contact element. The outer electrode includes a plurality of vertically-extending outer electrode sidewalls. The insulator is formed in an opening defined by the vertically-extending outer electrode sidewalls, and includes a plurality of vertically-extending insulator sidewalls. The inner electrode formed in an interior opening defined by the insulator. The outer electrode extension structure extends laterally from a particular vertically-extending outer electrode sidewall. The inner electrode contact element and outer electrode contact element are formed in a metal layer. The inner electrode contact element is electrically connected to the inner electrode, and the outer electrode contact element is electrically connected to the outer electrode extension structure.

A capacitor structure of memory is provided in the present invention, including structures of multiple cylindrical bottom electrode layers with bottoms contacting a substrate and extending vertically and upwardly from the substrate, the cylindrical shape of the bottom electrode layer has a sidewall with wavelike cross-section, and the wavelike cross-sections of adjacent bottom electrode layers are identical but shifted vertically by a distance, a capacitive dielectric layer on the bottom electrode layers, and a top electrode layer on the capacitive dielectric layer.

A semiconductor device includes: a first capacitor element that includes a first electrode, a second electrode, and a dielectric layer positioned between the first electrode and the second electrode; and a second capacitor element that includes a third electrode and an insulating layer positioned between the second electrode and the third electrode. The first capacitor element includes at least one first trench portion.