Abstract: A method of forming a ferroelectric random access memory (FeRAM) device includes: forming a layer stack over a substrate, where the layer stack includes alternating layers of a first dielectric material and a word line (WL) material; forming first trenches extending vertically through the layer stack; filling the first trenches, where filling the first trenches includes forming, in the first trenches, a ferroelectric material, a channel material over the ferroelectric material, and a second dielectric material over the channel material; after filling the first trenches, forming second trenches extending vertically through the layer stack, the second trenches being interleaved with the first trenches; and filling the second trenches, where filling the second trenches includes forming, in the second trenches, the ferroelectric material, the channel material over the ferroelectric material, and the second dielectric material over the channel material.

Abstract: A memory cell includes a thin film transistor over a semiconductor substrate. The thin film transistor includes a memory film contacting a word line; and an oxide semiconductor (OS) layer contacting a source line and a bit line, wherein the memory film is disposed between the OS layer and the word line; and a dielectric material separating the source line and the bit line. The dielectric material forms an interface with the OS layer. The dielectric material comprises hydrogen, and a hydrogen concentration at the interface between the dielectric material and the OS layer is no more than 3 atomic percent (at %).

Abstract: A memory cell includes a thin film transistor over a semiconductor substrate, the thin film transistor including: a memory film contacting a word line; and an oxide semiconductor (OS) layer contacting a source line and a bit line, wherein the memory film is disposed between the OS layer and the word line, wherein the source line and the bit line each comprise a first conductive material touching the OS layer, and wherein the first conductive material has a work function less than 4.6. The memory cell further includes a dielectric material separating the source line and the bit line.

Abstract: A transistor including a channel layer including an oxide semiconductor material and methods of making the same. The transistor includes a channel layer having a first oxide semiconductor layer having a first oxygen concentration, a second oxide semiconductor layer having a second oxygen concentration and a third oxide semiconductor layer having a third oxygen concentration. The second oxide semiconductor layer is located between the first semiconductor oxide layer and the third oxide semiconductor layer. The second oxygen concentration is lower than the first oxygen concentration and the third oxygen concentration.

Abstract: A device includes a dielectric layer, a conductive layer, electrode layers and an oxide semiconductor layer. The dielectric layer has a first surface and a second surface opposite to the first surface. The conductive layer is disposed on the first surface of the dielectric layer. The electrode layers are disposed on the second surface of the dielectric layer. The oxide semiconductor layer is disposed in between the second surface of the dielectric layer and the electrode layers, wherein the oxide semiconductor layer comprises a material represented by formula 1 (InxSnyTizMmOn). In formula 1, 0<x<1, 0?y<1, 0<z<1, 0<m<1, 0<n<1, and M represents at least one metal.

Abstract: A memory device includes a multi-layer stack, a channel layer, a memory material layer and at least three conductive pillars. The multi-layer stack is disposed on a substrate and includes a plurality of conductive layers and a plurality of dielectric layers stacked alternately. The channel layer penetrates through the plurality of conductive layers and the plurality of dielectric layers. The memory material layer is disposed between the channel layer and each of the plurality of conductive layers and the plurality of dielectric layers. The conductive pillars are surrounded by the channel layer and the memory material layer, wherein the at least three conductive pillars are electrically connected to conductive lines respectively.

Abstract: A memory device includes a first multi-layer stack, a channel layer, a charge storage layer, a first conductive pillar, and a second conductive pillar. The first multi-layer stack is disposed on a substrate and includes first conductive layers and first dielectric layers stacked alternately. The channel layer penetrates through the first conductive layers and the first dielectric layers, wherein the channel layer includes a first channel portion and a second channel portion separated from each other. The charge storage layer is disposed between the first conductive layers and the channel layer. The first conductive pillar is disposed between one end of the first channel portion and one end of the second channel portion. The second conductive pillar is disposed between the other end of the first channel portion and the other end of the second channel portion.

Abstract: A memory cell includes a ferroelectric (FE) material contacting a word line; and an oxide semiconductor (OS) layer contacting a source line and a bit line, wherein the FE material is disposed between the OS layer and the word line. The OS layer comprises: a first region adjacent the FE material, the first region having a first concentration of a semiconductor element; a second region adjacent the source line, the second region having a second concentration of the semiconductor element; and a third region between the first region and the second region, the third region having a third concentration of the semiconductor element, the third concentration is greater than the second concentration and less than the first concentration.

Abstract: A memory device includes a channel element, a memory element, and an electrode element. The channel element includes a first channel portion, a second channel portion, and a middle channel portion between the first channel portion and the second channel portion. The first channel portion has a first sidewall channel surface and a second sidewall channel surface opposing to the first sidewall channel surface. The middle channel portion has a third sidewall channel surface and a fourth sidewall channel surface opposing to the third sidewall channel surface. The first sidewall channel surface and the second sidewall channel surface of the first channel portion are outside the third sidewall channel surface and the fourth sidewall channel surface of the middle channel portion respectively. A memory cell is defined in the memory element between the channel element and the electrode element.

Abstract: A memory device comprises a stack of patterned conductor layers, at least a plurality of the layers comprising conductive strips including strips continuous with a pad and other strips isolated from the pad. An array of vertical pillars extends through the stack of patterned conductor layers, wherein memory cells are disposed at cross-points between the vertical pillars and patterned conductor layers. The array has an array boundary proximal to the pad. A first set of isolation blocks extends through the plurality of patterned conductor layers separating the strips continuous with the pad from the other strips isolated from the pad. A second set of isolation blocks inside the array boundary extends through the plurality of patterned conductor layers isolating the other strips from the pad.

Abstract: A memory device and a method for manufacturing the same are provided. A memory device includes a drain pillar structure, a source pillar structure, a charge trapping structure, a vertical channel structure and a gate structure. The drain pillar structure is formed in a first opening. The source pillar structure is formed in a second opening. The vertical channel structure and the vertical channel structure are formed in a hole partially overlapping the first opening and the second opening. The vertical channel structure is divided into two arc channel parts by the drain pillar structure and the source pillar structure. The gate structure surrounds the drain pillar structure, the source pillar structure and the vertical channel structure.

Abstract: A memory device includes a channel element, a memory element, and an electrode element. The channel element has an open ring shape. A memory cell is defined in the memory element between the channel element and the electrode element.

Abstract: A memory device and a method for manufacturing the same are provided. A memory device includes a drain pillar structure, a source pillar structure, a charge trapping structure, a vertical channel structure and a gate structure. The drain pillar structure is formed in a first opening. The source pillar structure is formed in a second opening. The vertical channel structure and the vertical channel structure are formed in a hole partially overlapping the first opening and the second opening. The vertical channel structure is divided into two arc channel parts by the drain pillar structure and the source pillar structure. The gate structure surrounds the drain pillar structure, the source pillar structure and the vertical channel structure.

Abstract: A stack of sacrificial layers is formed in a set of N levels. A first etch-trim mask having spaced apart first and second open etch regions is formed over the set. Two levels are etched through using the first etch-trim mask in each of M etch-trim cycles, where M is (N?1)/2 when N is odd and (N/2)?1 when N is even. One level is etched through using the first etch-trim mask in one etch-trim cycle when N is even. The first etch-trim mask is trimmed to increase the size of the first and second open etch regions, in each of etch-trim cycles C(i) for i going from 1 to T?1, where T is (N?1)/2 when N is odd and N/2 when N is even. A second etch mask is formed over the set, covering one of the open etch regions. One level is etched through using the second etch mask.

Abstract: A memory device includes a channel element, a memory element, and an electrode element. The channel element has an open ring shape. A memory cell is defined in the memory element between the channel element and the electrode element.

Abstract: A memory device includes a channel element, a memory element, and an electrode element. The channel element includes a first channel portion, a second channel portion, and a middle channel portion between the first channel portion and the second channel portion. The first channel portion has a first sidewall channel surface and a second sidewall channel surface opposing to the first sidewall channel surface. The middle channel portion has a third sidewall channel surface and a fourth sidewall channel surface opposing to the third sidewall channel surface. The first sidewall channel surface and the second sidewall channel surface of the first channel portion are outside the third sidewall channel surface and the fourth sidewall channel surface of the middle channel portion respectively. A memory cell is defined in the memory element between the channel element and the electrode element.

Abstract: A three-dimensional memory device includes a substrate, conductive layers and insulating layers, a storage layer, a first channel, a second channel and a first conductive plug. The conductive layers and insulating layers are alternately stacked over the substrate to form a multi-layer stacked structure. The storage layer penetrates through the multi-layer stacked structure, and has a first string portion and a second string portion that are spaced from each other. The first channel is located on a lateral side of the first string portion. The second channel is located on a lateral side of the second string portion. The first channel and the second channel have an upper channel portion and a lower channel portion. The first conductive plug is interconnected between the upper channel portion and the lower channel portion.

Abstract: A three-dimensional AND type flash memory and a manufacturing method thereof includes steps below is provided. A stack structure includes a first insulating layer and a first sacrificial layer is formed. A first pillar structure through the stack structure includes a second insulating layer and a second sacrificial layer surrounded by thereof is formed. A second pillar structure through the stack structure includes a channel layer and an insulating pillar surrounded by thereof is formed. The second sacrificial layer is located on both sides of the channel layer. The first sacrificial layer is removed. A lateral opening exposing a portion of the second insulating layer and the channel layer is formed. A gate insulating layer surrounding the exposed second insulating layer and channel layer is formed in the lateral opening. A gate layer is filled in the lateral opening. A conductive layer is used to replace the second sacrificial layer.

Abstract: Disclosed herein is a method of forming a semiconductor structure. The method includes the steps of: forming a first dielectric layer having a first through hole on a precursor substrate, in which the first through hole passes through the first dielectric layer; filling a sacrificial material in the first through hole; forming a second dielectric layer having a second through hole over the first dielectric layer, in which the second through hole exposes the sacrificial material in the first through hole, and the second through hole has a bottom width less than a top width of the first through hole; removing the sacrificial material after forming the second dielectric layer having the second through hole; forming a barrier layer lining sidewalls of the first and second through holes; and forming a conductive material in the first and second through holes.

Abstract: A 3D memory device includes a multi-layers stacking structure, a memory layer, a channel layer, and a switching element. The multi-layers stacking structure includes a plurality of conductive layers, a plurality of insulating layers, and an opening. The insulating layer and the conductive layer are stacked along a stacking direction in a staggered manner, and the opening passes through the conductive layer. The memory layer is disposed in the opening and at least partially overlaps the conductive layers. The channel layer is disposed in the opening and overlaps the memory layer. The switching element includes a channel plug disposed over the multi-layers stacking structure and electrically connecting to the channel layer, a first gate dielectric layer surrounding the channel plug, and at gate surrounding the gate dielectric layer.