Memory devices in which a memory cell includes a thin film select transistor and a capacitor (1TFT-1C). A 2D array of metal-insulator-metal capacitors may be fabricated over an array of the TFTs. Adjacent memory cells coupled to a same bitline may employ a continuous stripe of thin film semiconductor material. An isolation transistor that is biased to remain off may provide electrical isolation between adjacent storage nodes of a bitline. Wordline resistance may be reduced with a wordline shunt fabricated in a metallization level and strapped to gate terminal traces of the TFTs at multiple points over a wordline length. The capacitor array may occupy a footprint over a substrate. The TFTs providing wordline and bitline access to the capacitors may reside substantially within the capacitor array footprint. Peripheral column and row circuitry may employ FETs fabricated over a substrate substantially within the capacitor array footprint.

A method for fabricating a semiconductor device is provided. The method includes the actions of: providing a substrate comprising a preliminary pattern formed thereon; forming an opening through the preliminary pattern to expose a conductive portion in the substrate; forming a dielectric layer on a sidewall of the opening; performing a dry etching process to form a hole in the conductive portion; removing the dielectric layer; and depositing a conductive pattern over the sidewall of the opening and in the hole.

The present disclosure relates to a memory and a memory forming method. The memory forming method includes: providing an initial substrate; etching the initial substrate to form a plurality of capacitor holes and a plurality of recesses that are connected to the capacitor holes in a one-to-one corresponding manner and located below the capacitor holes; forming an isolation layer that connects adjacent ones of the recesses and fills up the recesses, and using the initial substrate remaining below the isolation layer as a substrate; and forming a capacitor in the capacitor hole.

Memory devices are described. The memory devices include a plurality of bit lines extending through a stack of alternating memory layers and dielectric layers. Each of the memory layers comprises a single crystalline-like silicon layer and includes a first word line, a second word line, a first capacitor, and a second capacitor. Methods of forming stacked memory devices are also described.

A method for fabricating a semiconductor device, including the steps of: providing a substrate comprising a preliminary pattern formed thereon; forming an opening through the preliminary pattern to expose a conductive portion in the substrate; forming a spacer on a sidewall of the opening; performing a wet etching process to form a hole in the conductive portion; removing the spacer; and depositing a conductive pattern over the sidewall of the opening and a surface of the hole.

A semiconductor device including a substrate and first and second packages thereon, the first package includes a first lower redistribution layer; a first core semiconductor stack thereon and including a first core chip and a first through via stacked on the first lower redistribution layer; and a first memory semiconductor stack on the first lower redistribution layer and including first memory chips stacked on the first lower redistribution layer, the second package includes a second lower redistribution layer; a second core semiconductor stack thereon and including a second core chip on the second lower redistribution layer; and a second memory semiconductor stack on the second lower redistribution layer and including second memory chips stacked on the second lower redistribution layer, the first through via penetrates the first core semiconductor stack, and the first and second lower redistribution layers are electrically connected to each other through the first through via.

A memory device having a capacitor structure and a method of forming the same are provided. The memory device includes a substrate; a dielectric layer disposed on the substrate; and a plurality of capacitor structures respectively disposed in the dielectric layer. Each capacitor structure includes: a cup-shaped lower electrode; a first upper electrode conformally covering an outer surface of the cup-shaped lower electrode; a first capacitor dielectric layer disposed between the outer surface of the cup-shaped lower electrode and the first upper electrode; a second upper electrode conformally covering an inner surface of the cup-shaped lower electrode, wherein the second upper electrode is electrically connected to the first upper electrode by at least one connection via; and a second capacitor dielectric layer disposed between the inner surface of the cup-shaped lower electrode and the second upper electrode.

A semiconductor device includes a landing pad and a capacitor disposed on and electrically connected to the landing pad. The capacitor includes a cylindrical bottom electrode, a dielectric layer and a top electrode. The cylindrical bottom electrode is disposed on an in contact with the landing pads, wherein an inner surface the cylindrical bottom electrode includes a plurality of protruding portions, and an outer surface of the cylindrical bottom electrode includes a plurality of concaved portions. The dielectric layer is conformally disposed on the inner surface and the outer surface of the cylindrical bottom electrode, and covering the protruding portions and the concaved portions. The top electrode is conformally disposed on the dielectric layer over the inner surface and the outer surface of the cylindrical bottom electrode.

Described herein are arrays of embedded dynamic random-access memory (eDRAM) cells that use TFTs as selector transistors. When at least some selector transistors are implemented as TFTs, different eDRAM cells may be provided in different layers above a substrate, enabling a stacked architecture. An example stacked TFT based eDRAM includes one or more memory cells provided in a first layer over a substrate and one or more memory cells provided in a second layer, above the first layer, where at least the memory cells in the second layer, but preferably the memory cells in both the first and second layers, use TFTs as selector transistors. Stacked TFT based eDRAM allows increasing density of memory cells in a memory array having a given footprint area, or, conversely, reducing the footprint area of the memory array with a given memory cell density.

Some embodiments include an integrated capacitor assembly having a conductive pillar supported by a base, with the conductive pillar being included within a first electrode of a capacitor. The conductive pillar has a first upper surface. A dielectric liner is along an outer surface of the conductive pillar and has a second upper surface. A conductive liner is along the dielectric liner and is included within a second electrode of the capacitor. The conductive liner has a third upper surface. One of the first and third upper surfaces is above the other of the first and third upper surfaces. The second upper surface is at least as high above the base as said one of the first and third upper surfaces. Some embodiments include memory arrays having capacitors with pillar-type first electrodes.