[Object] To provide a semiconductor element capable of realizing an element having a nonvolatile memory capable of stably storing highly integrated data, a nonvolatile memory device, a multiply-accumulate operation device, and a method of manufacturing the semiconductor element. [Solving means] A semiconductor element according to an embodiment of the present technology includes a plurality of cell blocks. The plurality of cell blocks are configured by connecting a plurality of cell portions in series with each other, the plurality of cell portions each having a MOSFET for controlling conduction of a channel portion and a resistor connected in parallel to the channel portion, and configured to store data by a resistance level set for each of the plurality of cell portions.

A method of writing data to a memory array of three-terminal memory cells includes simultaneously programming a first subset of memory cells in a first column of the memory array to a first logic level by activating a first select line of the first column and a first bit line of the first column, and simultaneously programming a second subset of memory cells in the first column to the first logic level by activating the first select line and a second bit line of the first column.

A memory circuit includes a memory array including a plurality of memory cells, each memory cell of the plurality of memory cells including an n-type channel layer including a metal oxide material, and a gate structure overlying and adjacent to the n-type channel layer, the gate structure including a conductive layer overlying a ferroelectric layer. The memory circuit is configured to apply a gate voltage to each memory cell of the plurality of memory cells in first and second write operations, the gate voltage has a positive polarity and a first magnitude in the first write operation and a negative polarity and a second magnitude greater than the first magnitude in the second write operation.

Methods, systems, and devices for a read algorithm for a memory device are described. When performing a read operation, the memory device may access a memory cell to retrieve a value stored by the memory cell. The memory device may compare a set of reference voltages with a signal output by the memory cell based on accessing the memory cell. Thus, the memory device may determine a set of candidate values stored by the memory cell, where each candidate value is associated with one of the reference voltages. The memory device may determine and output the value stored by the memory cell based on determining the set of candidate values. In some cases, the memory device may determine the value stored by the memory cell based on performing an error control operation on each of the set of candidate values to detect a quantity of errors within each candidate value.

Methods, systems, and devices for feedback for multi-level signaling in a memory device are described. A receiver may use a modulation scheme to communicate information with a host device. The receiver may include a first circuit, a second circuit, a third circuit, and a fourth circuit. Each of the first circuit, the second circuit, the third circuit, and the fourth circuit may determine, for a respective clock phase, a voltage level of a signal modulated using the modulation scheme. The receiver may include a first feedback circuit, a second feedback circuit, a third feedback circuit, and a fourth feedback circuit. The first feedback circuit that may use information received from the first circuit at the first clock phase and modify the signal input into the second circuit for the second clock phase.

Dual-precision analog memory cells and arrays are provided. In some embodiments, a memory cell, comprises a non-volatile memory element having an input terminal and at least one output terminal; and a volatile memory element having a plurality of input terminals and an output terminal, wherein the output terminal of the volatile memory element is coupled to the input terminal of the non-volatile memory element, and wherein the volatile memory element comprises: a first transistor coupled between a first supply and a common node, and a second transistor coupled between a second supply and the common node; wherein the common node is coupled to the output terminal of the volatile memory element; and wherein gates of the first and second transistors are coupled to respective ones of the plurality of input terminals of the volatile memory element.

A FeFET configured as a 2-bit storage device that includes a gate stack including a ferroelectric layer over a semiconductor substrate; and the ferroelectric layer includes dipoles; and a first set of dipoles at the first end of the ferroelectric layer has a first polarization; and a second set of dipoles at the second end of the ferroelectric layer has a second polarization, the first and second polarizations of the corresponding first and second sets of dipoles representing storage of 2 bits, wherein a first bit of the 2-bit storage device being configured to be read by application of a read voltage to the source region and a do-not-disturb voltage to the drain region; and a second bit of the 2-bit storage device being configured to be read by application of the do-not-disturb voltage to the source region and the read voltage to the drain region.

Disclosed is a content addressable memory device including a memory cell array including a plurality of memory cells, each of which has a ferroelectric tunnel field effect transistor (FeTFET), and a match amplifier connected to the plurality of memory cells through a plurality of match lines. The FeTFET includes a first doped region including a first conductivity type, a second doped region including a second conductivity type different from the first conductivity type, a channel region formed between the first doped region and the second doped region, and a gate formed on the channel region and including a ferroelectric layer.

A semiconductor device includes a substrate including, in a first area, a first semiconductor channel and coupled to a portion of a first memory layer, and first, second, and third conductive structures. The first and third conductive structures are coupled to end portions of a sidewall of the first semiconductor channel, with the second conductive structure coupled to a middle portion of the sidewall. The semiconductor device includes, in a second area, a second semiconductor channel and coupled to a first portion of a second memory layer, and fourth and fifth conductive structures. The fourth and fifth conductive structures are coupled to end portions of a sidewall of the second semiconductor channel, with no vertically extending conductive structure interposed between the fourth and fifth conductive structures.

A memory cell includes a write bit line, a read word line, a write transistor, and a read transistor. The write transistor is coupled between the write bit line and a first node. The read transistor is coupled to the write transistor by the first node. The read transistor includes a ferroelectric layer, a drain terminal of the read transistor is coupled to the read word line, and a source terminal of the read transistor is coupled to a second node. The write transistor is configured to set a stored data value of the memory cell by a write bit line signal that adjusts a polarization state of the read transistor. The polarization state corresponds to the stored data value.