Some embodiments include apparatuses and methods of forming such apparatuses. One of the apparatus includes first memory cells located in different levels in a first portion of the apparatus, second memory cells located in different levels in a second portion of the apparatus, a switch located in a third portion of the apparatus between the first and second portions, first and second control gates to access the first and second memory cells, an additional control gate located between the first and second control gates to control the switch, a first conductive structure having a thickness and extending perpendicular to the levels in the first portion of the apparatus, a first dielectric structure between the first conductive structure and charge-storage portions of the first memory cells, a second dielectric structure having a second thickness between the second conductive structure and a sidewall of the additional control gate, the second thickness being greater than the first thickness.

The present invention discloses a method of fast erasing an EEPROM with low-voltages. The EEPROM includes a transistor structure is formed in a semiconductor substrate and the transistor structure includes a first electric-conduction gate. Same type ions are implanted into a region of the semiconductor substrate, which is near interfaces of a source, a drain and the first electric-conduction gate, or ion-doped regions of the source and the drain, to increase the ion concentration thereof, whereby to reduce the voltage differences required for erasing. Moreover, the source or the drain is floated during erasing to achieve rapid erasing for a large number of memory cells. In addition to the EEPROM with a single gate transistor structure, the present invention also applies to the EEPROM with a single floating gate transistor structure.

An alternating stack of insulating layers and sacrificial material layers is formed over a substrate, and memory stack structures are formed through the alternating stack. A backside trench is formed through the alternating stack, and backside recesses are formed by removing the sacrificial material layers. An undoped aluminum oxide backside blocking dielectric layer is formed in the backside recesses and on sidewalls the backside trench. A portion of the undoped aluminum oxide backside blocking dielectric layer located at an upper end of the backside trench is converted into a carbon-doped aluminum oxide layer. An electrically conductive material is deposited in the backside recesses and at peripheral regions of the backside trench. The electrically conductive material at the peripheral regions of the backside trench is removed by an etch process, with the carbon-doped aluminum oxide layer providing etch resistivity during the etch process.

A semiconductor device includes a memory cell formed on a semiconductor substrate. The memory cell includes a first source region and a first drain region that are formed in the semiconductor substrate and a first selection gate, and a first floating gate disposed in series between the first source region and the first drain region. A first floating gate transistor including the first drain region and the first floating gate has a threshold set lower than a threshold of a first selection gate transistor including the first source region and the first selection gate.

First and second memory cells are arranged on a semiconductor substrate. The memory cell includes, between a first or second source region and a first or second drain, a configuration in which a first or second selection gate and a first or second floating gate are arranged in series. The first memory cell and the second memory cell are adjacent to each other in a first direction. A first signal line extending in the first direction and connected to the first and second selection gates is further provided. The first and second source regions are configured to share a first region. The first selection gate extends in a direction different from the first direction.

A single-poly non-volatile memory unit includes: a semiconductor substrate having a first conductivity type; first, second and third OD regions disposed on the semiconductor substrate and separated from each other by an isolation region, wherein the first OD region and the second OD region are formed in a first ion well, and the first ion well has a second conductivity type; a first memory cell disposed on the first OD region, a second memory cell disposed on the second OD region. The first memory cell and the second memory cell exhibit an asymmetric memory cell layout structure with respect to an axis. An erase gate is disposed in the third OD region.

A non-volatile memory cell includes a floating-gate transistor, a select transistor, and a coupling structure. The floating-gate transistor is deposited in a P-well and includes a gate terminal coupled to a floating gate which is a first polysilicon layer, a drain terminal coupled to a bit line, and a source terminal coupled to a first node. The select transistor is deposited in the P-well and includes a gate terminal coupled to a select gate which is coupled to a word line, a drain terminal coupled to the first node, and a source terminal coupled to the source line. The floating-gate transistor and the select transistor are N-type transistors. The coupling structure is formed by extending the first polysilicon layer to overlap a control gate, in which the control gate is a P-type doped region in an N-well and the control gate is coupled to a control line.

A semiconductor device includes a semiconductor substrate, and a nonvolatile memory cell disposed on the semiconductor substrate. The nonvolatile memory cell includes a field-effect transistor for data writing, and a field-effect transistor for data readout that is adjacent to the field-effect transistor for data writing. Each of the field-effect transistor for data writing and the field-effect transistor for data readout includes a gate insulating film formed on the semiconductor substrate, a floating gate formed on the gate insulating film, and diffusion layers configuring a source region and a drain region on respective sides of the floating gate viewed in the thickness direction of the semiconductor substrate. The thickness of the gate insulating film of the field-effect transistor for data readout, and the thickness of the gate insulating film of the field-effect transistor for data writing, are different.

A three-dimensional memory device includes alternating stacks of insulating layers and electrically conductive layers located over a semiconductor material layer, and memory stack structures extending through one of the alternating stacks. Laterally-undulating backside trenches are present between alternating stacks, and include a laterally alternating sequence of straight trench segments and bulging trench segments. Cavity-containing dielectric fill structures and contact via structures are present in the laterally-undulating backside trenches. The contact via structures are located within the bulging trench segments. The contact via structures are self-aligned to sidewalls of the alternating stacks. Additional contact via structures may vertically extend through a dielectric alternating stack of a subset of the insulating layers and dielectric spacer layers laterally adjoining one of the alternating stacks.

An alternating stack of insulating layers and spacer material layers is formed over a substrate. A staircase region having stepped surfaces is formed by patterning the alternating stack. Memory opening fill structures are formed in a memory array region, and support pillar structures are formed in the staircase region. Each of the memory stack structures includes a memory film and a vertical semiconductor channel. The support pillar structures include first support pillar structures and having a first maximum lateral dimension and second support pillar structures having a second maximum lateral dimension that is less than the first maximum lateral dimension and interlaced with the first support pillar structures. The sacrificial material layers are replaced with electrically conductive layers. The second support pillar structures are positioned interstitially among the first support pillar structures and contact via structures that are formed on the electrically conductive layers to provide additional structural support.