Some embodiments include an integrated assembly having a laterally-extending container-shaped first capacitor electrode, and having a laterally-extending container-shaped second capacitor electrode laterally offset from the first capacitor electrode. Capacitor dielectric material lines interior surfaces and exterior surfaces of the container-shaped first and second capacitor electrodes. A shared capacitor electrode extends vertically between the first and second capacitor electrodes, and extends along the lined interior and exterior surfaces of the first and second capacitor electrodes. Some embodiments include methods of forming integrated assemblies.

A capacitor that includes a substrate, a first inner electrode and a second inner electrode provided above the first main surface of the substrate, the second inner electrode arranged so as to face the first inner electrode; a dielectric layer between the first inner electrode and the second inner electrode; a first intermediate electrode connected to the first inner electrode at a plurality of first locations; first surface electrodes electrically connected to the first intermediate electrode; and a second surface electrode connected to the second inner electrode at a plurality of second locations.

A device structure according to the present disclosure includes a passivation layer, a first conductor plate layer disposed on the passivation layer, a second conductor plate layer disposed over the first conductor layer, a third conductor plate layer disposed over the second conductor layer, and a fourth conductor plate layer disposed over the third conductor layer. The second conductor plate layer encloses the first conductor plate layer and the fourth conductor plate layer encloses the third conductor plate layer. The device structure, when used in a back-end-of-line passive device, reduces leakage and breakdown due to corner discharge effect.

Capacitor structures with low capacitances are disclosed. In one example, a capacitor structure is disclosed. The capacitor structure includes a first electrode and a second electrode. The first electrode comprises a first metal finger. The second electrode comprises a second metal finger and a third metal finger that are parallel to each other and to the first metal finger. The first metal finger is formed between the second metal finger and the third metal finger. The capacitor structure further includes: a fourth metal finger formed as a dummy metal finger between the first metal finger and the second metal finger, and a fifth metal finger formed as a dummy metal finger between the first metal finger and the third metal finger. The fourth metal finger and the fifth metal finger are parallel to the first metal finger.

A semiconductor device includes a plurality of semiconductor patterns stacked to be spaced apart from each other in a first direction, perpendicular to an upper surface of a substrate, and extending in a second direction, parallel to the upper surface of the substrate, a plurality of first conductive patterns extending in a third direction, perpendicular to the first direction and the second direction, on the plurality of semiconductor patterns, a plurality of second conductive patterns extending in the first direction on the substrate, a plurality of capacitors electrically connected to the plurality of semiconductor patterns, respectively, and at least one epitaxial layer disposed to be in contact with at least one of both end surfaces of at least one of the plurality of semiconductor patterns and including an impurity.

Semiconductor devices and methods of forming the same are provided. In one embodiment, a semiconductor device includes a contact feature in a first dielectric layer, a first passivation layer over the contact feature, a bottom conductor plate layer disposed over the first passivation layer and including a first plurality of sublayers, a second dielectric layer over the bottom conductor plate layer, a middle conductor plate layer disposed over the second dielectric layer and including a second plurality of sublayers, a third dielectric layer over the middle conductor plate layer, a top conductor plate layer disposed over the third dielectric layer and including a third plurality of sublayers, and a second passivation layer over the top conductor plate layer.

The present application discloses a semiconductor device and a method for fabricating the semiconductor device. The semiconductor device includes a first stack structure positioned on a first substrate, a first impurity region and a second impurity region respectively positioned on opposing sides of the first stack structure and operatively associated with the first stack structure, a second stack structure positioned above the first stack structure with a middle insulation layer interposed therebetween, and a third impurity region positioned on one side of the second stack structure and electrically coupled to the second impurity region. The first stack structure includes a plurality of first semiconductor layers and a plurality of gate assemblies alternatively arranged. The plurality of gate assemblies includes a gate dielectric and a gate electrode. The second stack structure includes a plurality of second semiconductor layers and a plurality of capacitor sub-units alternatively arranged. The plurality of capacitor sub-units including a capacitor dielectric and a capacitor electrode.

A method used in forming integrated circuitry comprises forming an array of structures elevationally through a stack comprising first and second materials. The structures project vertically relative to an outermost portion of the first material. Energy is directed onto vertically-projecting portions of the structures and onto the second material in a direction that is angled from vertical and that is along a straight line between immediately-adjacent of the structures to form openings into the second material that are individually between the immediately-adjacent structures along the straight line. Other embodiments, including structure independent of method, are disclosed.

Decoupling structures are provided. The decoupling structures may include first conductive patterns, second conductive patterns and a unitary supporting structure that structurally supports the first conductive patterns and the second conductive patterns. The decoupling structures may also include a common electrode disposed between ones of the first conductive patterns and between ones of the second conductive patterns. The first conductive patterns and the common electrode are electrodes of a first capacitor, and the second conductive patterns and the common electrode are electrodes of a second capacitor. The unitary supporting structure may include openings when viewed from a plan perspective. The first conductive patterns and the second conductive patterns are horizontally spaced apart from each other with a separation region therebetween, and none of the openings extend into the separation region.

Metal e-fuse structure formed during back-end-of-line during processing and integral with on-chip metal-insulator-metal (MIM) capacitor (MIMcap). The metal e-fuse structures are extensions of MIMcap electrodes and are structured to isolate BEOL MIM capacitors for trimming and/or to isolate shorted or rendered highly leaky due to in process, or service induced defects. In one embodiment, the method incorporates the integral, co-processed metal e-fuse in series between the MIM capacitor and an active circuit. When a high current passes through the e-fuse element, the e-fuse element is rendered highly resistive or electrically open thereby disconnecting the MIM capacitor or electrode plate from the active circuitry. The e-fuse structure may comprise a thin neck portion(s) or zig-zag neck portion that extend from an MIMcap electrode away from the MIMcap between two inter-level interconnect via structures.