A method of fabricating a semiconductor device includes forming a first stack of semiconductor layers on a substrate. The first stack of semiconductor layers includes alternating first and second semiconductor strips. The first and second semiconductor strips includes first and second semiconductor materials, respectively. The method also includes removing the first semiconductor strips to form voids between the second semiconductor strips in the first stack of semiconductor layers. The method further includes depositing a dielectric structure layer and a first conductive fill material in the voids to surround the second semiconductor strips. Further, the method includes removing the second semiconductor strips to form a second set of voids, and depositing a third semiconductor material in the second sets of voids.

Some embodiments include an integrated assembly having a pillar of semiconductor material. The pillar has a base region, and bifurcates into two segments which extend upwardly from the base region. The two segments are horizontally spaced from one another by an intervening region. A conductive gate is within the intervening region. A first source/drain region is within the base region, a second source/drain region is within the segments, and a channel region is within the segments. The channel region is adjacent to the conductive gate and is vertically disposed between the first and second source/drain regions. Some embodiments include methods of forming integrated assemblies.

A tridimensional memory cell array includes vertically stacked first conductive lines, vertically stacked second conductive lines, and first and second flights of steps. First and second conductive lines extend along a first direction. The second conductive lines are disposed at a distance along a second direction from the first conductive lines. First and second directions are orthogonal. Along the first direction, the first flights are disposed at opposite ends of the first conductive lines and the second flights are disposed at opposite ends of the second conductive lines. The first and second flights include landing pads and connective lines alternately disposed along the first direction. The landing pads are wider than the connective lines along the second direction. Along the second direction, landing pads of the first flights face connective lines of the second flights and landing pads of the second flights face connective lines of the first flights.

A semiconductor storage device includes a plurality of gate electrodes, a semiconductor layer facing the plurality of gate electrodes, a gate insulating layer arranged between each of the plurality of gate electrodes and the semiconductor layer. The gate insulating layer contains oxygen (O) and hafnium (Hf) and has an orthorhombic crystal structure. A plurality of first wirings is connected to the respective gate electrodes. A controller is configured to execute a write sequence and an erasing sequence by applying certain voltages to at least one of the first wirings. The controller is further configured to increase either a program voltage to be applied to the first wirings in the write sequence or an application time of the program voltage in the write sequence after a total number of executions of the write sequence or the erasing sequence has reached a particular number.

A method of manufacturing a semiconductor device, the method including providing a substrate including a first region and a second region such that the second region is separated from the first region; forming a metal oxide film on the first region of the substrate and the second region of the substrate; forming an upper metal material film on the metal oxide film on the first region of the substrate such that the upper metal material film does not overlap the metal oxide film on the second region of the substrate; and simultaneously annealing the upper metal material film and the metal oxide film to form a ferroelectric insulating film on the first region of the substrate and form a paraelectric insulating film on the second region of the substrate.

A semiconductor memory device includes a semiconductor layer, a gate electrode, a gate insulating film disposed therebetween, first and second wirings connected to the semiconductor layer, and a third wiring connected to the gate electrode and is configured to execute a write operation, an erase operation, and a read operation. In the write operation, a write voltage of a first polarity is supplied between the third wiring and at least one of the first wiring or the second wiring. In the erase operation, an erase voltage of a second polarity is supplied between the third wiring and at least one of the first wiring or the second wiring. In the read operation, the write voltage or a voltage having a larger amplitude than that of the write voltage is supplied between the third wiring and at least one of the first wiring or the second wiring.

A semiconductor memory device capable of improving performance by the use of a charge storage layer including a ferroelectric material is provided. The semiconductor memory device includes a substrate, a tunnel insulating layer contacting the substrate, on the substrate, a charge storage layer contacting the tunnel insulating layer and including a ferroelectric material, on the tunnel insulating layer, a barrier insulating layer contacting the charge storage layer, on the charge storage layer, and a gate electrode contacting the barrier insulating layer, on the barrier insulating layer.

A semiconductor memory device is implemented as strings of storage transistors, where the storage transistors in each string have drain terminals connected to a bit line and gate terminals connected to respective word lines. In some embodiments, the semiconductor memory device includes a reference bit line structure to provide a reference bit line signal for read operation. The reference bit line structure configures word line connections to provide a reference bit line to be used with a storage transistor being selected for read access. The reference bit line structure provides a reference bit line having the same electrical characteristics as an active bit line and is configured so that no storage transistors are selected when a word line is activated to access a selected storage transistor associated with the active bit line.

A semiconductor chip including a semiconductor substrate, an interconnect structure and memory devices is provided. The semiconductor substrate includes first transistors, and the first transistors are negative capacitance field effect transistors. The interconnect structure is disposed over the semiconductor substrate and electrically connected to the first transistors, and the interconnect structure includes stacked interlayer dielectric layers, interconnect wirings, and second transistors embedded in the stacked interlayer dielectric layers. The memory devices are embedded in the stacked interlayer dielectric layers and electrically connected to the second transistors.

A method of forming a three-dimensional (3D) memory device includes: forming a layer stack over a substrate, the layer stack including alternating layers of a first dielectric material and a second dielectric material; forming trenches extending through the layer stack; replacing the second dielectric material with an electrically conductive material to form word lines (WLs); lining sidewalls and bottoms of the trenches with a ferroelectric material; filling the trenches with a third dielectric material; forming bit lines (BLs) and source lines (SLs) extending vertically through the third dielectric material; removing portions of the third dielectric material to form openings in the third dielectric material between the BLs and the SLs; forming a channel material along sidewalls of the openings; and filling the openings with a fourth dielectric material.