Methods, systems, and devices for sensing a memory with shared sense components are described. A device may activate a word line and a plate line each coupled with a set of memory cells, where each memory cell of the set of memory cells is coupled with a respective digit line of a set of digit lines. The device may activate a set of switching components to couple each digit line of the set of digit lines with a respective sense component of a set of sense components, where each switching component of the set of switching components is coupled with a respective memory cell of the set of memory cells. The device may sense the set of memory cells based on activating the word line and the plate line and based on coupling the set of digit lines with the set of sense components.

An apparatus has a controller and an array of memory cells, including a first section comprising a plurality of rows and a second section comprising a plurality of rows. The controller configured to, in association with wear leveling, transfer data stored in a first row of the first section from the first row to a register, transfer the data from the register to a destination row of the second section while data in a second row of the first section is being sensed.

Methods, systems, and devices related to data relocation via a cache 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 some cases, the memory device may transfer data from a first address of the memory array to the signal development cache. The memory device may transfer the data stored in the signal development cache to a second address of the memory array based on a parameter associated with the first address of the memory array satisfying a criterion for performing data relocation.

A device is disclosed. The device includes a substrate that includes a base portion and a fin portion that extends upward from the base portion, an insulator layer on sides and top of the fin portion, a first conductor layer on a first side surface of the insulator layer, a second conductor layer on a second side surface of the insulator layer, and a ferroelectric layer on portions of a top surface of the base portion, a portion of the insulator layer below the first conductor layer, a side and top surface of the first conductor layer, a top surface of the insulator layer above the fin portion, a side and top surface of the second conductor layer, and a portion of the insulator layer below the second conductor layer. A word line conductor is on the top surface of the ferroelectric layer.

Methods, systems, and devices for activity-based data protection in a memory device are described. In one example, a memory device may include a set memory sections each having memory cells configured to be selectively coupled with access lines of the respective memory section. A method of operating the memory device may include determining a quantity of access operations performed on a set of sections of a memory device, selecting at least one of the sections for a voltage adjustment operation based on the determined quantity of access operations, and performing the voltage adjustment operation on the selected section. The voltage adjustment operation may include applying an equal voltage to opposite terminals of the memory cells, which may allow built-up charge, such as leakage charge accumulating from access operations of the selected memory section, to dissipate from the memory cells of the selected section.

A memory is provided which comprises a capacitor including non-linear polar material. The capacitor may have a first terminal coupled to a node (e.g., a storage node) and a second terminal coupled to a plate-line. The capacitors can be a planar capacitor or non-planar capacitor (also known as pillar capacitor). The memory includes a transistor coupled to the node and a bit-line, wherein the transistor is controllable by a word-line, wherein the plate-line is parallel to the bit-line. The memory includes a refresh circuitry to refresh charge on the capacitor periodically or at a predetermined time. The refresh circuit can utilize one or more of the endurance mechanisms. When the plate-line is parallel to the bit-line, a specific read and write scheme may be used to reduce the disturb voltage for unselected bit-cells. A different scheme is used when the plate-line is parallel to the word-line.

Methods, systems, and devices for memory cell sensing using an averaged reference voltage are described. A memory device may generate the averaged reference voltage that is specific to operating conditions or characteristics. The averaged reference voltage thus may track variations in cell use and cell characteristics. The memory device may generate the averaged reference voltage by shorting together reference nodes to determine an average of values associated with the reference nodes. The reference nodes may be associated with a codeword, which may store values corresponding to the reference nodes. The codeword may be balanced or nearly balanced to include equal or nearly equal quantities of different logic values.

Methods, systems, and devices for a single plate configuration and memory array operation are described. A non-volatile memory array may utilize a single plate to cover a subset of the array. One or more memory cells of the subset may be selected by operating the plate and an access line of an unselected memory cell at a fixed voltage. A second voltage may be applied to an access line of the selected cell, and subsequently reduced to perform an access operation. Removing the applied voltage may allow for the memory cell to undergo a recovery period prior to a subsequent access operation.

Methods, systems, and devices for operating a ferroelectric memory cell or cells are described. In some examples, multi-level accessing, sensing, and other operations for ferroelectric memory may be based on sensing multiple charges, including a first charge associated with a dielectric of the memory cell and a second charge associated with a polarization of the memory cell. In some cases, multi-level accessing, sensing, and other operations may be based on transferring a first charge associated with a dielectric of the memory cell to a sense amplifier, isolating the sense amplifier, activating the sense amplifier, transferring a second charge associated with a polarization of the memory cell to the sense amplifier, and activating the sense amplifier a second time.

Methods, systems, and devices for techniques to perform a sense operation are described. In some examples, a memory device may include a pair of transistor to precharge a digit line. A first transistor of the pair of transistors may be coupled with a first node and a second transistor of the pair of transistors may be coupled with a second node. In some cases, the first node and the second node may be selectively coupled via a transistor. The first and second transistors may be activated to precharge the first and second nodes. In some examples, a pulse may be applied to a capacitor coupled with the second node to transfer a charge to the digit line. In some cases, the cascode transistor may maintain or control the voltage of the digit line to be at or below an upper operating voltage of the memory cell.