A semiconductor device with split gate flash memory cell structure includes a substrate having a first area and a second area, at least a first cell formed in the first area and at least a second cell formed in the second area. The first cell includes a first dielectric layer formed on the substrate, a floating gate (FG), a word line and an erase gate (EG) formed on the first dielectric layer, an interlayer dielectric (ILD) layer, an inter-gate dielectric layer and a control gate (CG). The FG is positioned between the word line and the EG, and the ILD layer is formed on the word line and the EG, wherein the ILD layer has a trench exposing the FG. The inter-gate dielectric layer is formed in the trench as a liner, and the CG formed in the trench is surrounded by the inter-gate dielectric layer.

The present disclosure relates to an integrated circuit (IC) that includes a HKMG hybrid non-volatile memory (NVM) device and that provides small scale and high performance, and a method of formation. In some embodiments, the integrated circuit includes a memory region having a NVM device with a pair of control gate electrodes separated from a substrate by corresponding floating gates. A pair of select gate electrodes are disposed at opposite sides of the pair of control gate electrodes comprise polysilicon. A logic region is disposed adjacent to the memory region and has a logic device with a metal gate electrode disposed over a logic gate dielectric and having bottom and sidewall surfaces covered by a high-k gate dielectric layer.

A method of making a monolithic three dimensional NAND string is provided. A stack of alternating layers of a first material and a second material different from the first material is formed over a substrate. The stack is etched to form at least one opening in the stack. A charge storage material layer is formed on a sidewall of the at least one opening. A tunnel dielectric layer is formed on the charge storage material layer in the at least one opening. A semiconductor channel material is formed on the tunnel dielectric layer in the at least one opening. The first material layers are selectively removed to expose side wall of the charge storage material layer. A blocking dielectric is formed on the exposed side wall of the charge storage material layer. Control gates are formed on the blocking dielectric.

Provided is a split-gate embedded flash memory cell and method for forming the same. The flash memory cell includes split-gate transistors in which the control gate is aligned with respect to the floating gate without the use of a photolithographic patterning operation to pattern the material from which the control gates are formed. An anisotropic blanket etching operation is used to form the floating gates of the split-gate floating gate transistors alongside sidewalls of a sacrificial layer. Local oxidation of silicon (LOCOS) methods are not needed to form the inter-gate dielectric and therefore high integrity is maintained for the floating transistor gates. The floating transistor gates are formed of charge storage material such as silicon nitride, Si.sub.3N.sub.4 in some embodiments.

A flash memory device and method of making the same are disclosed. The flash memory device is located on a substrate and includes a floating gate electrode, a tunnel dielectric layer located between the substrate and the floating gate electrode, a smaller length control gate electrode and a control gate dielectric layer located between the floating gate electrode and the smaller length control gate electrode. The length of a major axis of the smaller length control gate electrode is less than a length of a major axis of the floating gate electrode.

Some embodiments include a memory device and methods of forming the memory device. One such memory device includes a first group of memory cells, each of the memory cells of the first group being formed in a cavity of a first control gate located in one device level of the memory device. The memory device also includes a second group of memory cells, each of the memory cells of the second group being formed in a cavity of a second control gate located in another device level of the memory device. Additional apparatus and methods are described.

A semiconductor arrangement and method of forming the same are described. A semiconductor arrangement includes a first gate structure on a first side of an active area and a second gate structure on a second side of the active area, where the first gate structure and the second gate structure share the active area. A method of forming the semiconductor arrangement includes forming a deep implant of the active area before forming the first gate structure, and then forming a shallow implant of the active area. Forming the deep implant prior to forming the first gate structure alleviates the need for an etching process that degrades the first gate structure. The first gate structure thus has a desired configuration and is able to be formed closer to other gate structures to enhance device density.

Some embodiments of the present disclosure relate to method of forming a memory device. In some embodiments, the method may be performed by forming a floating gate over a first dielectric on a substrate. A control gate is formed over the floating gate and first and second spacers are formed along sidewalls of the control gate. The first and second spacers extend past outer edges of an upper surface of the floating gate. An etching process is performed on the first and second spacers to remove a portion of the first and second spacers that extends past the outer edges of the upper surface of the floating gate along an interface between the first and second spacers and the floating gate.

A semiconductor device having good characteristics without variation and a method of manufacturing the same are provided. A part of a conductive layer for a floating gate is removed by using a spacer insulating film, a first insulating film, and a second insulating film as a mask. A floating gate having a tip portion is formed from the conductive layer for the floating gate, and a part of an insulating layer for a gate insulating film is exposed from the floating gate. The tip portion of the floating gate is further exposed by selectively removing the second insulating film among the second insulating film, the insulating layer for the gate insulating film, and the spacer insulating film.

A memory cell disposed on a substrate has a first gate structure and a second gate structure. The memory cell includes a first heavily doped region adjacent to an outer side of the first gate structure. Further, a first lightly doped drain (LDD) region with a first type dopant is between the first heavily doped region and the outer side of the first gate structure. A pocket doped region with a second type dopant is overlapping with the first LDD region. The second type dopant is opposite to the first type dopant in conductive type. A second heavily doped region is adjacent to an outer side of the second gate structure, opposite to the first heavily doped region. A second LDD region with the first type dopant is disposed between the first gate structure and the second gate structure.