A staggered memory cell architecture staggers memory cells on opposite sides of a shared bit line preserves memory cell density, while increasing the distance between such memory cells, thereby reducing the possibility of a disturb. In one implementation, the memory cells along a first side of a shared bit line are connected to a set of global word lines provided underneath the memory structure, while the memory cells on the other side of the shared bit line—which are staggered relative to the memory cells on the first side—are connected to global word lines above the memory structure.

A storage transistor has a tunnel dielectric layer and a charge-trapping layer between a channel region and a gate electrode, wherein the charge-tapping layer has a conduction band offset that is less than the lowering of the tunneling barrier in the tunnel dielectric layer when a programming voltage is applied, such that electrons direct tunnel into the charge-trapping layer. The conduction band of the charge-trapping layer is has a value between −1.0 eV and 2.3 eV. The storage transistor may further include a barrier layer between the tunnel dielectric layer and the charge-trapping layer, the barrier layer having a conduction band offset less than the conduction band offset of the charge-trapping layer.

In one embodiment, a semiconductor device includes a stacked film alternately including a plurality of electrode layers and a plurality of insulating layers. The device further includes a first insulator, a charge storage layer, a second insulator and a first semiconductor layer that are disposed in order in the stacked film. The device further includes a plurality of first films disposed between the first insulator and the plurality of insulating layers. Furthermore, at least one of the first films includes a second semiconductor layer.

A semiconductor structure includes a first-conductivity-type well located in a semiconductor substrate, a semiconductor active area region located adjacent to the a first-conductivity-type well, a first transistor including a source region, a drain region, a channel region located between the source region and the drain region, a gate dielectric layer located over the channel region and a gate electrode located over the gate dielectric layer, such that the transistor is located on the semiconductor active area region, and a cutoff gate electrode located over the semiconductor active area region, and between the first transistor and the first-conductivity-type well.

A semiconductor device includes a substrate having at least a trench formed therein. A conductive material fills a lower portion of the trench. A barrier layer is between the conductive material and the substrate. An insulating layer is in the trench and completely covers the conductive material and the barrier layer, wherein a portion of the insulating layer covering the barrier layer has a bird's peak profile.

Semiconductor memory having both volatile and non-volatile modes and methods of operation. A semiconductor storage device includes a plurality of memory cells each having a floating body for storing, reading and writing data as volatile memory. The device includes a floating gate or trapping layer for storing data as non-volatile memory, the device operating as volatile memory when power is applied to the device, and the device storing data from the volatile memory as non-volatile memory when power to the device is interrupted.

A memory device includes a transistor and a memory cell. The transistor includes a first gate electrode, a second gate electrode, a channel layer, and a gate dielectric layer. The second gate electrode is over the first gate electrode. The channel layer is located between the first gate electrode and the second gate electrode. The gate dielectric layer is located between the channel layer and the second gate electrode. The memory cell is sandwiched between the first gate electrode and the channel layer.

To allow a metal oxide film composed mainly of O and at least one of Hf and Zr to exhibit ferroelectric properties. After deposition of a hafnium oxide film on a semiconductor substrate via an insulating film, the semiconductor substrate is exposed to microwaves to selectively heat the hafnium oxide film. This makes it possible to form a larger number of orthorhombic crystals in the crystals of the hafnium oxide film. The hafnium oxide film thus obtained can therefore exhibit ferroelectric properties without adding, thereto, an impurity such as Si. This means that the hafnium oxide film having a reverse size effect can be used as a ferroelectric film of a ferroelectric memory cell and contributes to the manufacture of a miniaturized ferroelectric memory cell.

A method of forming a semiconductor device comprises forming sacrificial structures and support pillars on a material. Tiers are formed over the sacrificial structures and support pillars and tier pillars and tier openings are formed to expose the sacrificial structures. One or more of the tier openings comprises a greater critical dimension than the other tier openings. The sacrificial structures are removed to form a cavity. A cell film is formed over sidewalls of the tier pillars, the cavity, and the one or more tier openings. A fill material is formed in the tier openings and adjacent to the cell film and a portion removed from the other tier openings to form recesses adjacent to an uppermost tier. Substantially all of the fill material is removed from the one or more tier openings. A doped polysilicon material is formed in the recesses and the one or more tier openings. A conductive material is formed in the recesses and in the one or more tier openings. An opening is formed in a slit region and a dielectric material is formed in the opening. Additional methods, semiconductor devices, and systems are disclosed.

Microelectronic devices include a stack structure with a vertically alternating sequence of insulative structures and conductive structures arranged in tiers. A series of slit structures extends through the stack structure and divides the stack structure into a series of blocks. In a progressed portion of the series of blocks, each block comprises an array of pillars extending through the stack structure of the block. Also, each block—in the progressed portion—has a different block width than a block width of a neighboring block of the progressed portion of the series of blocks. At least one pillar, of the pillars of the array of pillars in the progressed portion, exhibits bending. Related methods and electronic systems are also disclosed.