A NAND flash memory array includes a select line having a first edge region containing a first portion of floating gate material and a second edge region containing a second portion of floating gate material, and having a central region between the first edge region and the second edge region where no floating gate material is present.

A method to prevent loss of data of transistor-based memory unit including bulk, source and drain formed on bulk and first tunnel oxide, floating gate, second tunnel oxide and control gate stacked up on channel between source and drain is disclosed to include steps of: erasing the floating gate, using weak electric field inject small amount of electrons into floating gate, enabling small amount of electrons to remain in floating gate to keep channel between source and drain electrically conducted, enabling small amount of electrons in floating gate to repel against electrons in first tunnel oxide and second tunnel oxide so as avoid electron accumulation in first tunnel oxide and second tunnel oxide and allow normal data access floating gate, and using electric field of normal write to inject electrons in floating gate so as to prevent channel conduction between source and drain and allow writing data into floating gate.

An alternating stack of insulating layers and sacrificial material layers are formed over a substrate. Memory stack structures are formed through the alternating stack. A backside trench is formed and the sacrificial material layers are replaced with electrically conductive layers. After formation of an insulating spacer in the trench, an epitaxial pedestal structure is grown from a semiconductor portion underlying the backside trench. A source region is formed by introducing dopants into the epitaxial pedestal structure and an underlying semiconductor portion during and/or after epitaxial growth. Alternatively, the backside trench can be formed concurrently with formation of memory openings. An epitaxial pedestal structure can be formed concurrently with formation of epitaxial channel portions at the bottom of each memory opening. After formation and subsequent removal of a dummy trench fill structure in the backside trench, a source region is formed by introducing dopants into the epitaxial pedestal structure.

An alternating stack of insulating layers and sacrificial material layers can be formed over a substrate. Memory stack structures and a backside trench are formed through the alternating stack. Backside recesses are formed by removing the sacrificial material layers from the backside trench selective to the insulating layers. A cobalt-semiconductor alloy portion is formed in each backside recess by reacting cobalt and a semiconductor material. Conductive material in the backside trench can be removed by an etch to electrically isolate cobalt-containing alloy portions located in different backside recesses. Electrically conductive layers including a respective cobalt-semiconductor alloy portion can be employed as word lines of a three-dimensional memory device.

A semiconductor memory device according to an embodiment includes a tunnel insulating layer arranged above a first semiconductor layer, a charge accumulation layer arranged above the tunnel insulating layer, a block insulating layer arranged above the charge accumulation layer, and a control gate arranged above the block insulating layer, wherein the charge accumulation layer includes a second semiconductor layer and a metal film arranged above the second semiconductor layer, and the second semiconductor layer includes a dividing film made of an insulator and a divided portion divided by the dividing film.

Embodiments of a simple and cost-free multi-time programmable (MTP) structure for non-volatile memory cells are presented. The memory cell includes a substrate, a first transistor having a select gate and a second transistor having a floating gate. The select and floating gates are adjacent to one another and disposed over a transistor well. The transistors include first and second S/D regions disposed adjacent to the sides of the gates. A control gate is disposed over a control well. The control gate is coupled to the floating gate and includes a control capacitor. An erase terminal is decoupled from the control capacitor and transistors.

Protective dielectrics are discussed generally herein. In one or more embodiments, a three-dimensional vertical memory may include a protective dielectric material. A device may include an etch stop material, a first control gate (CG) over the etch stop material, a first CG recess adjacent the first CG, a trench adjacent the first CG recess, and an at least partially oxidized polysilicon on at least a portion of the etch stop material. The at least partially oxidized polysilicon may line a sidewall of the trench and may line the first CG recess.

Various embodiments provide a memory cell that includes a vertical selection gate, a floating gate extending above the substrate, wherein the floating gate also extends above a portion of the vertical selection gate, over a non-zero overlap distance, the memory cell comprising a doped region implanted at the intersection of a vertical channel region extending opposite the selection gate and a horizontal channel region extending opposite the floating gate.

A method of forming an integrated DMOS transistor/EEPROM cell includes forming a first mask over a substrate, forming a drift implant in the substrate using the first mask to align the drift implant, simultaneously forming a first floating gate over the drift implant, and a second floating gate spaced apart from the drift implant, forming a second mask covering the second floating gate and covering a portion of the first floating gate, forming a base implant in the substrate using an edge of the first floating gate to self-align the base implant region, and simultaneously forming a first control gate over the first floating gate and a second control gate over the second floating gate. The first floating gate, first control gate, drift implant, and base implant form components of the DMOS transistor, and the second floating gate and second control gate form components of the EEPROM cell.

An alternating stack of insulating layers and sacrificial material layers is formed over a substrate. After formation of a memory opening, all surfaces of the memory opening are provided as silicon oxide surfaces by formation of at least one silicon oxide portion. A silicon nitride layer is formed in the memory opening. After formation of a memory stack structure, backside recesses can be formed employing the silicon oxide portions as an etch stop. The silicon oxide portions can be subsequently removed employing the silicon nitride layer as an etch stop. Physically exposed portions of the silicon nitride layer can be removed selective to the memory stack structure. Damage to the outer layer of the memory stack structure can be minimized or eliminated by successive use of etch stop structures. Electrically conductive layers can be subsequently formed in the backside recesses.