The present disclosure provides a semiconductor structure and a manufacturing method thereof. The manufacturing method includes: forming a capacitor on a substrate, where a first support layer is provided between parts of the first electrodes in the capacitor away from the substrate; removing part of a second electrode and part of a first dielectric layer to expose a surface of the first support layer away from the substrate; forming, on the surface of the first support layer away from the substrate, a second support layer having a first hole structure; forming, on a side surface of the first hole structure, a third electrode in contact with the first electrode; forming a second dielectric layer covering the third electrode and being in contact with the first dielectric layer; and forming, on a side surface of the second dielectric layer, a fourth electrode in contact with the second electrode.

The present disclosure provides a capacitor and a manufacturing method thereof, and a semiconductor device. The capacitor includes a plurality of bottom electrodes, a top electrode structure, a dielectric layer, and a gap filling layer, where the top electrode structure is formed on one side of each of the plurality of bottom electrodes, one side of the dielectric layer is in contact with the plurality of bottom electrodes and the other side is in contact with the top electrode structure, and the gap filling layer fills remaining gaps between the plurality of bottom electrodes.

The present invention provides a manufacturing method of a semiconductor device and a semiconductor device. A semiconductor device is provided, the semiconductor device includes a substrate, a stacked structure disposed on the substrate, the substrate comprises a cell array region, a peripheral circuit region and a middle region between the cell array region and the peripheral circuit region, a first trench located in the middle region, a second support layer located on an upper surface of the stacked structure, wherein parts of the second support layer is disposed in the first trench, and a capacitor structure located in the cell array region.

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.

A two-terminal device comprises a bottom electrode. A device element is formed upon the bottom electrode. The two-terminal device also comprises a top electrode that is formed upon the device element. The bottom electrode and the top electrode are aligned. The bottom electrode and top electrode also have a same width and depth.

A MIM capacitor and related methods of fabricating the MIM capacitor. The MIM capacitor includes a bottom capacitor plate including a plurality of trenches defined therein, and a top capacitor plate. The MIM capacitor also includes a capacitor insulating layer disposed between the top capacitor plate and the bottom capacitor plate and within the plurality of trenches. Further, the MIM capacitor includes a first electrode electrically connected to the bottom capacitor plate, and a second electrode electrically connected to the top capacitor plate.

The present disclosure generally relates to semiconductor structures and, more particularly, to a deep trench capacitor, integrated structures and methods of manufacture. The structure includes: a conductive material formed on an underside of an insulator layer and which acts as a back plate of a deep trench capacitor; an inner conductive layer extending through the insulator layer and an overlying substrate; and a dielectric liner between the inner conductive material and the conductive material, and formed on a sidewall of an opening within the insulator layer and the overlying substrate.

A nanoscale structure includes an array of pillars over an underlying layer, a separation wall layer including first separation walls formed over sidewalls of the pillars, and a block co-polymer (BCP) layer formed over the separation wall layer and filling gaps between the pillars. The BCP layer is phase-separated to include first domains that provide second separation walls formed over the first separation walls and second domains that are separated from each other by the first domains.

A method for forming a semiconductor structure includes providing a semiconductor substrate, which at least includes discrete conducting layers in the semiconductor substrate; forming discretely arranged supporting structures on the semiconductor substrate, capacitor openings being included between the supporting structures; forming lower electrodes on sidewalls of the supporting structures, the lower electrodes being electrically connected with the conducting layers; forming a capacitor dielectric layer covering tops of the supporting structures, sidewalls of the lower electrodes, and bottoms of the capacitor openings; and forming an upper electrode covering the capacitor dielectric layer, to form capacitor structures.

A method for forming semiconductor structure includes: providing a semiconductor substrate, which at least includes discrete conducting layers in the semiconductor substrate; forming discretely arranged supporting structures on the semiconductor substrate, lower portions of the supporting structures including a bottom conducting layers, and capacitor openings being included between the supporting structures, and the bottom conducting layers being electrically connected with the conducting layers; forming lower electrodes on sidewalls of the supporting structures, the lower electrodes being electrically connected with the bottom conducting layers; forming a capacitor dielectric layer covering tops of the supporting structures, sidewalls of the lower electrodes, and bottoms of the capacitor openings; and forming an upper electrode covering the capacitor dielectric layer), to form a capacitor structure. A semiconductor structure is also provided.