A method comprises forming a control gate structure over a substrate, depositing a memory gate layer over the substrate, applying a first etching process to the memory gate layer to form a memory gate structure, wherein, after applying the first etching process, a remaining portion of the memory gate layer is an L-shaped structure, forming a first spacer along a sidewall of the memory gate structure and forming a second spacer over the memory gate structure.

A quantum nano-tip (QNT) thin film, such as a silicon nano-tip (SiNT) thin film, for flash memory cells is provided to increase erase speed. The QNT thin film includes a first dielectric layer and a second dielectric layer arranged over the first dielectric layer. Further, the QNT thin film includes QNTs arranged over the first dielectric layer and extending into the second dielectric layer. A ratio of height to width of the QNTs is greater than 50 percent. A QNT based flash memory cell and a method for manufacture a SiNT based flash memory cell are also provided.

A method of forming a pair of memory cells that includes forming a polysilicon layer over and insulated from a semiconductor substrate, forming a pair of conductive control gates over and insulated from the polysilicon layer, forming first and second insulation layers extending along inner and outer side surfaces of the control gates, removing portions of the polysilicon layer adjacent the outer side surfaces of the control gates, forming an HKMG layer on the structure and removing portions thereof between the control gates, removing a portion of the polysilicon layer adjacent the inner side surfaces of the control gates, forming a source region in the substrate adjacent the inner side surfaces of the control gates, forming a conductive erase gate over and insulated from the source region, forming conductive word line gates laterally adjacent to the control gates, and forming drain regions in the substrate adjacent the word line gates.

A nonvolatile memory device includes a plurality of twin cells arrayed on a substrate. Each of the plurality of twin cells includes a drain mesa protruding from a surface of a substrate. A first source and a second source are disposed in the substrate and spaced apart from the drain mesa. A first floating gate overlaps with a first sidewall surface of the drain mesa and extends onto the first source, and a second floating gate overlaps with a second sidewall surface of the drain mesa and extends onto the second source. Related methods are also provided.

A memory device has first and second memory cells in and over a substrate. A first doped region is in a first active region. A top surface of the first active region is substantially coplanar with a top surface of the first doped region. A control gate is over the first doped region and extends over a first side of the first doped region and over a second side of the first doped region. A charge storage layer is between the first control gate and the first active region including between the first select gate and the first doped region. A first select gate is over the first active region on the first side of the first doped region and adjacent to the control gate. A second select gate is over the first active region on the second side of the first doped region and adjacent to the control gate.

A method includes forming a selection gate and a control gate for a flash memory cell in a memory device region. The selection gate and the control gate are over a semiconductor substrate. A protection layer is formed to cover the selection gate and the control gate. Stacked layers are formed in a logic device region, wherein the stacked layers extend to overlap the selection gate and the control gate. The stacked layers are patterned to form a gate stack for a logic device in the logic device region. After the patterning, an etching step is performed to etch a residue of the stacked layers in a boundary region of the memory device region. After the etching step, the protection layer is removed from the memory device region. Source and drain regions are formed for each of the flash memory cell and the logic device.

A method of forming a pair of memory cells that includes forming a polysilicon layer over and insulated from a semiconductor substrate, forming a pair of conductive control gates over and insulated from the polysilicon layer, forming first and second insulation layers extending along inner and outer side surfaces of the control gates, removing portions of the polysilicon layer adjacent the outer side surfaces of the control gates, forming an HKMG layer on the structure and removing portions thereof between the control gates, removing a portion of the polysilicon layer adjacent the inner side surfaces of the control gates, forming a source region in the substrate adjacent the inner side surfaces of the control gates, forming a conductive erase gate over and insulated from the source region, forming conductive word line gates laterally adjacent to the control gates, and forming drain regions in the substrate adjacent the word line gates.

There is provided a monolithic three dimensional array of charge storage devices which includes a plurality of device levels, wherein at least one surface between two successive device levels is planarized by chemical mechanical polishing.

Provided are a weighting device that may be driven at a low voltage and is capable of embodying multi-level weights, a neural network, and a method of operating the weighting device. The weighting device includes a switching layer that may switch between a high resistance state and a low resistance state based on a voltage applied thereto and a charge trap material layer that traps or discharges charges according to a resistance state of the switching layer. The weighting device may be used for controlling a weight in a neural network.

A semiconductor device includes a first pillar-shaped semiconductor layer, a first selection gate insulating film, a first selection gate, a first gate insulating film, a first contact electrode, a first bit line connected to an upper portion of the first pillar-shaped semiconductor layer and an upper portion of the first contact electrode, a second pillar-shaped semiconductor layer, a layer including a first charge storage layer, a first control gate, a layer including a second charge storage layer and formed above the first control gate, a second control gate, a second gate insulating film, a second contact electrode having an upper portion connected to an upper portion of the second pillar-shaped semiconductor layer, and a first lower internal line that connects a lower portion of the first pillar-shaped semiconductor layer and a lower portion of the second pillar-shaped semiconductor layer.