A semiconductor structure includes a substrate, a storage capacitor unit, a transistor, and an electrical connection structure. The storage capacitor unit is located at an array area and includes: N insulation posts, distributed in a direction parallel to a surface of the substrate; a bottom electrode layer; a top electrode layer, directly facing the bottom electrode layer; and a capacitor dielectric layer, located between the top and bottom electrode layers. One of the bottom or top electrode layers corresponding to the N insulation posts is a continuous film layer, and the other is discrete film layers. The transistor is located at a circuit area and includes a capacitor control terminal located in the substrate of the circuit area. The electrical connection structure is electrically connected to the capacitor control terminal, and extends from the circuit area to the array area to come into contact with a corresponding discrete film layer.

A semiconductor structure and a method for forming semiconductor structure are provided. The method includes: after a plurality of capacitor vias are formed in a support layer and a sacrifice layer, external electrode layers are formed on sidewall surfaces of the capacitor vias; a dielectric layer is formed on a sidewall surface of each external electrode layer; remaining sacrifice layer between the external electrode layers is removed to form a cavity at a position where remaining sacrifice layer has been removed; an internal electrode layer is formed on a surface of the dielectric layer and a bottom surface of each capacitor via; a first conductive layer completely filling the cavity is formed, where the first conductive layer is in contact with a respective one of the external electrode layers; and a second conductive layer completely filling a remaining part of each capacitor via is formed on the internal electrode layer.

A pumping capacitor is provided. The pumping capacitor includes: first, second, third and fourth electrodes that are separately formed on a substrate; a first pumping capacitor group, wherein i first cell capacitors have lower electrodes formed on the first pad electrode and upper electrodes connected to a plate electrode, and (n−i) first cell capacitors have lower electrodes formed on the second pad electrode and upper electrodes connected to the plate electrode; and a second pumping capacitor group, wherein i second cell capacitors have lower electrodes formed on the fourth pad electrode and upper electrodes connected to the plate electrode, and (n−i) second cell capacitors have lower electrodes formed on the third pad electrode and upper electrodes connected to the plate electrode. The first pumping capacitor group and the second pumping capacitor group are connected in series, and the second pad electrode and the third pad electrode are floated.

A semiconductor device includes a plurality of electrode structures formed on a substrate; and an upper supporter group and a lower supporter between upper ends and lower ends of the plurality of electrode structures The upper supporter group includes a plurality of supporters, and at least some of the plurality of supporters each have an upper surface and a lower surface. One of the upper surface and the lower surface has a curved profile, and the other surface has a flat profile.

A for preparing a semiconductor device includes forming a first dielectric layer over a semiconductor substrate, and forming an etch stop layer over the first dielectric layer. The method also includes forming a second dielectric layer over the etch stop layer, and forming a first metal plug penetrating through the second dielectric layer, the etch stop layer and the first dielectric layer. The first metal plug protrudes from the second dielectric layer. The method further includes performing an anisotropic etching process to partially remove the first metal plug such that the first metal plug has a convex top surface, and forming a third dielectric layer covering the second dielectric layer and the convex top surface of the first metal plug. In addition, the method includes forming a second metal plug over the first metal plug.

Some embodiments include integrated memory having an array of access transistors. Each access transistor includes an active region which has a first source/drain region, a second source/drain region and a channel region. The active regions of the access transistors include semiconductor material having elements selected from Groups 13 and 16 of the periodic table. First conductive structures extend along rows of the array and have gating segments adjacent the channel regions of the access transistors. Heterogenous insulative regions are between the gating segments and the channel regions. Second conductive structures extend along columns of the array, and are electrically coupled with the first source/drain regions. Storage-elements are electrically coupled with the second source/drain regions. Some embodiments include a transistor having a semiconductor oxide channel material. A conductive gate material is adjacent to the channel material. A heterogenous insulative region is between the gate material and the channel material.

A semiconductor device includes a metal-insulator-metal (MIM) capacitor. The MIM capacitor includes: electrodes including one or more first electrodes and one or more second electrodes; and one or more insulating layers disposed between adjacent electrodes. The MIM capacitor is disposed in an interlayer dielectric (ILD) layer disposed over a substrate. The one or more first electrodes are connected to a side wall of a first via electrode disposed in the ILD layer, and the one or more second electrodes are connected to a side wall of a second via electrode disposed in the ILD layer. In one or more of the foregoing or following embodiments, the one or more insulating layers include a high-k dielectric material.

The present application provides a method for manufacturing a memory and a memory, which relate to the technical field of memory devices and are used to solve the technical problems of relatively low storage speed and storage efficiency. The manufacturing method includes: providing a substrate, a plurality of capacitor contact pads being disposed at intervals in the substrate; forming a first recess on a first surface of each of the capacitor contact pads; forming conductive pillars in the first recesses, upper end surfaces of the conductive pillars being flush with the first surfaces of the capacitor contact pads; and forming a plurality of capacitors on the substrate, the plurality of the capacitors and the plurality of the capacitor contact pads corresponding one to one and being electrically connected; wherein a first plate of each of the capacitors covers the corresponding conductive pillar.

A method for manufacturing a dynamic random access memory device includes providing a semiconductor substrate and forming a highly doped diffusion region in a surface of the semiconductor substrate. A wordline structure is then deposited on the surface of the semiconductor substrate, where the wordline structure includes an electrically conductive gate layer. An opening is further formed in the wordline structure, where the opening is located at a first end of and extending to the highly doped diffusion region. A semiconductor pillar is then formed in the opening by selective epitaxial growth. An end of the semiconductor pillar is then doped and the doped end is connected with a memory element.

Some embodiments include a transistor having an active region containing semiconductor material. The semiconductor material includes at least one element selected from Group 13 of the periodic table in combination with at least one element selected from Group 16 of the periodic table. The active region has a first region, a third region offset from the first region, and a second region between the first and third regions. A gating structure is operatively adjacent to the second region. A first carrier-concentration-gradient is within the first region, and a second carrier-concentration-gradient is within the third region. Some embodiments include methods of forming integrated assemblies.