Some embodiments include methods of forming charge storage transistor gates and standard FET gates in which common processing is utilized for fabrication of at least some portions of the different types of gates. FET and charge storage transistor gate stacks may be formed. The gate stacks may each include a gate material, an insulative material, and a sacrificial material. The sacrificial material is removed from the FET and charge storage transistor gate stacks. The insulative material of the FET gate stacks is etched through. A conductive material is formed over the FET gate stacks and over the charge storage transistor gate stacks. The conductive material physically contacts the gate material of the FET gate stacks, and is separated from the gate material of the charge storage transistor gate stacks by the insulative material remaining in the charge storage transistor gate stacks. Some embodiments include gate structures.

A semiconductor device, the device including: a first silicon layer including first single crystal silicon; an isolation layer disposed over the first silicon layer; a first metal layer disposed over the isolation layer; a second metal layer disposed over the first metal layer; a first level including a plurality of transistors, the first level disposed over the second metal layer, where the isolation layer includes an oxide to oxide bond surface, where the plurality of transistors include a second single crystal silicon region; and a third metal layer disposed over the first level, where a typical first thickness of the third metal layer is at least 50% greater than a typical second thickness of the second metal layer.

A semiconductor apparatus includes a plurality of semiconductor devices. The semiconductor devices each include a ferroelectric layer, a conductive metal oxide layer, and a semiconductor layer, between two electrodes. The conductive metal oxide layer may be between the ferroelectric layer and the semiconductor layer. The ferroelectric layer, the conductive metal oxide layer, and the semiconductor layer may all include a metal oxide. The conductive metal oxide layer may include one or more materials selected from the group consisting of an indium oxide, a zinc oxide, a tin oxide, and any combination thereof.

A semiconductor apparatus includes a plurality of semiconductor devices. The semiconductor devices each include a ferroelectric layer, a conductive metal oxide layer, and a semiconductor layer, between two electrodes. The conductive metal oxide layer may be between the ferroelectric layer and the semiconductor layer. The ferroelectric layer, the conductive metal oxide layer, and the semiconductor layer may all include a metal oxide. The conductive metal oxide layer may include one or more materials selected from the group consisting of an indium oxide, a zinc oxide, a tin oxide, and any combination thereof.

Disclosed is a semiconductor device having a memory cell which comprises a transistor having a control gate and a storage gate. The storage gate comprises an oxide semiconductor and is able to be a conductor and an insulator depending on the potential of the storage gate and the potential of the control gate. Data is written by setting the potential of the control gate to allow the storage gate to be a conductor, supplying a potential of data to be stored to the storage gate, and setting the potential of the control gate to allow the storage gate to be an insulator. Data is read by supplying a potential for reading to a read signal line connected to one of a source and a drain of the transistor and detecting the change in potential of a bit line connected to the other of the source and the drain.

A transistor comprises a pair of source/drain regions having a channel region there-between. A transistor gate construction is operatively proximate the channel region. The channel region comprises a direction of current flow there-through between the pair of source/drain regions. The channel region comprises at least one of GaP, GaN, and GaAs extending all along the current-flow direction. Each of the source/drain regions comprises at least one of GaP, GaN, and GaAs extending completely through the respective source/drain region orthogonal to the current-flow direction. The at least one of the GaP, the GaN, and the GaAs of the respective source/drain region is directly against the at least one of the GaP, the GaN, and the GaAs of the channel region. Each of the source/drain regions comprises at least one of elemental silicon and metal material extending completely through the respective source/drain region orthogonal to the current-flow direction. Other embodiments are disclosed.

A three-dimensional semiconductor device includes a bottom word line stack with a top via plug region and a bottom via plug region, a top word line stack over the bottom word line stack; top via plugs disposed in the top via plug region; and bottom via plugs disposed in the bottom via plug region. The bottom via plugs include upper bottom via plugs extending vertically and completely through the top word line stack; and lower bottom via plugs extending vertically and partially through the bottom word line stack. An interface between the bottom word line stack and the top word line stack and interfaces of the lower bottom via plugs and the upper bottom via plugs are located at a same level. A horizontal width of an upper end of each of the lower bottom via plugs is greater than a horizontal width of a lower end of each of the upper bottom via plugs.

A memory system includes a first memory cell array which is a nonvolatile memory cell array, a controller configured to control read and write of data, a first data latch group used for input and output of the data between the controller and the first memory cell array, and at least one second data latch group in which stored data is maintained when the data is read from the first memory cell array by the controller. The controller is configured to store management information in the at least one second data latch group when or before executing a read process for the data from the first memory cell array, the management information being in a second memory cell array and used for read of the data.

A nonvolatile memory device comprises a first semiconductor layer including, an upper substrate, and a memory cell array in which a plurality of word lines on the upper substrate extend in a first direction and a plurality of bit lines extend in a second direction. The nonvolatile memory device comprises a second semiconductor layer under the first semiconductor layer in a third direction perpendicular to the first and second directions, the second semiconductor layer including, a lower substrate, and a substrate control circuit on the lower substrate and configured to output a bias voltage to the upper substrate. The second semiconductor layer is divided into first through fourth regions, each of the first through fourth regions having an identical area, and the substrate control circuit overlaps at least a portion of the first through fourth regions in the third direction.

A semiconductor storage device includes a circuit region formed on a semiconductor substrate, and a guard ring region spaced from one side of the circuit region by a predetermined distance. The guard ring region extends in a first direction, the first direction being a direction in which the one side of the circuit region extends, includes a guard ring line, an element isolation region, a first defect trapping layer, a second defect trapping layer. The first defect trapping layer extends from a boundary location between the circuit region and the element isolation region to a location spaced from a boundary location between the element isolation region and the guard ring line by an offset distance toward the element isolation region in the second direction.