A 1S-1T ferroelectric memory cell is provided that include a transistor and a two-terminal selector device. The transistor exhibits a low conductive state and a high conductive state (channel resistance), depending on drive voltage. The two-terminal selector device exhibits one of an ON-state and an OFF-state depending upon whether the transistor is in its low conductive state or its high conductive state. The transistor may be, for instance, a ferroelectric gate vertical transistor. Modulation of a polarization state of ferroelectric material of the vertical transistor may be utilized to switch the state of the selector device. The memory cell may thus selectively be operated in one of an ON-state and an OFF-state depending upon whether the selector device is in its ON-state or OFF-state.

Methods, systems, and devices for operating a ferroelectric memory cell or cells are described. A ferroelectric memory cell may be selected using a selection component that is in electronic communication with a sense amplifier and a ferroelectric capacitor of a ferroelectric memory cell. A voltage applied to the ferroelectric capacitor may be sized to increase the signal sensed during a read operation. The ferroelectric capacitor may be isolated from the sense amplifier during the read operation. This isolation may avoid stressing the ferroelectric capacitor which may otherwise occur due to the applied read voltage and voltage introduce by the sense amplifier during the read operation.

Methods, systems, and devices related to signal development caching in a memory device are described. In one example, a memory device in accordance with the described techniques may include a memory array, a sense amplifier array, and a signal development cache configured to store signals (e.g., cache signals, signal states) associated with logic states (e.g., memory states) that may be stored at the memory array (e.g., according to various read or write operations). In various examples, accessing the memory device may include accessing information from the signal development cache, or the memory array, or both, based on various mappings or operations of the memory device.

Methods, systems, and devices for a hybrid memory device are described. The hybrid memory device may include volatile and non-volatile memory cells on a single substrate, or die. The non-volatile memory cells may have ferroelectric capacitors and the volatile memory cells may have paraelectric or linear dielectric capacitors for their respective logic storage components. In some examples, the volatile memory cells may be used as a cache for the non-volatile memory cells. Or the non-volatile memory cells may be used as a back-up for the volatile memory cells. By placing both types of cells on a single die, rather than separate dies, various performance metrics may be improved, including those related to power consumption and operation speed.

Methods, systems, and devices for a memory device with multiplexed digit lines are described. In some cases, a memory cell of the memory device may include a storage component and a selection component that includes two transistors. A first transistor may be coupled with a word line and a second transistor may be coupled with a select line to selectively couple the memory cell with a digit line. The selection component, in conjunction with a digit line multiplexing component, may support a sense component common to a set of digit lines. In some cases, the digit line of the set may be coupled with the sense component during a read operation, while the remaining digit lines of the set are isolated from the sense component.

A memory array includes hybrid memory cells, wherein each hybrid memory cell includes a transistor-type memory including a memory film extending on a gate electrode; a channel layer extending on the memory film; a first source/drain electrode extending on the channel layer; and a second source/drain electrode extending along the channel layer; and a resistive-type memory including a resistive memory layer, wherein the resistive memory layer extends between the second source/drain electrode and the channel layer.

A memory device and a manufacturing method are provided. The memory device includes a substrate, a transistor, and a memory cell. The substrate has a semiconductor device and a dielectric structure disposed on the semiconductor device. The transistor is disposed over the dielectric structure and is electrically coupled with the semiconductor device. The semiconductor device includes a gate, a channel layer, source drain regions, and a stack of a gate dielectric layer and a first ferroelectric layer. The gate and the source and drain regions are disposed over the dielectric structure. The channel layer is located between the source and drain regions. The stack of the gate dielectric layer and the first ferroelectric layer is disposed between the gate and the channel layer. The memory cell is disposed over the transistor and is electrically connected to one of the source and drain regions. The memory cell includes a ferromagnetic layer or a second ferroelectric layer.

A memory cell includes a transistor including a memory film extending along a word line; a channel layer extending along the memory film, wherein the memory film is between the channel layer and the word line; a source line extending along the memory film, wherein the memory film is between the source line and the word line; a first contact layer on the source line, wherein the first contact layer contacts the channel layer and the memory film; a bit line extending along the memory film, wherein the memory film is between the bit line and the word line; a second contact layer on the bit line, wherein the second contact layer contacts the channel layer and the memory film; and an isolation region between the source line and the bit line.

A memory cell includes a thin film transistor over a semiconductor substrate. The thin film transistor includes a memory film contacting a word line; and an oxide semiconductor (OS) layer contacting a source line and a bit line, wherein the memory film is disposed between the OS layer and the word line; and a dielectric material separating the source line and the bit line. The dielectric material forms an interface with the OS layer. The dielectric material comprises hydrogen, and a hydrogen concentration at the interface between the dielectric material and the OS layer is no more than 3 atomic percent (at %).

A memory cell includes a thin film transistor over a semiconductor substrate, the thin film transistor including: a memory film contacting a word line; and an oxide semiconductor (OS) layer contacting a source line and a bit line, wherein the memory film is disposed between the OS layer and the word line, wherein the source line and the bit line each comprise a first conductive material touching the OS layer, and wherein the first conductive material has a work function less than 4.6. The memory cell further includes a dielectric material separating the source line and the bit line.