Disclosed is a threshold voltage-programmable field effect transistor-based (e.g., a ferro-electric field effect transistor (FeFET)-based) memory circuit employing source-line and/or bit-line-applied variable programming assist voltages. For single-bit data storage in a FeFET, decremental programming assist voltages are selectively applied by a voltage driver to the source-line and/or the bit-line connected to a FeFET during repeat programming processes when previous attempts at programming have failed. For multi-bit data storage in a FeFET, different programming assist voltages are associated with different multi-bit data values and at least one specific programming assist voltage is applied by a voltage driver to the source-line and/or the bit-line connected to a selected FeFET during a programming process to achieve storage of a specific multi-bit data value. Optionally, multiple FeFETs in the same row can be currently programmed with different multi-bit data values. Optionally, different decremental programming assist voltages are applied if/when repeat programming processes are required.

Methods, systems, and devices for cell data bulk reset are described. In some examples, a logic state (e.g., a first logic state) may be written to one or more memory cells based on an associated memory device transitioning power states. To write the first logic state to the memory cells, a first subset of digit lines may be driven to a first voltage and a plate may be driven to a second voltage. While the digit lines and plate are driven to the respective voltages, one or more word lines may be driven to the second voltage. In some instances, the word lines may be driven to the second voltage based on charge sharing occurring between adjacent word lines.

Ferroelectric components, such as the ferroelectric field effect transistors (FeFETs), ferroelectric capacitors and ferroelectric diodes described above may be operated as multi-level memory cells as described by the present invention. Storing multiple bits of information in each multi-level memory cell may be performed by a controller coupled to an array of the ferroelectric components configured as ferroelectric memory cells. The controller may execute the steps of receiving a bit pattern for writing to a multi-level memory cell comprising a ferroelectric layer; selecting a pulse duration for applying a write pulse to the memory cell based, at least in part, on the received bit pattern; and applying at least one write pulse to the memory cell having the selected pulse duration, in which the at least one write pulse creates a remnant polarization within the ferroelectric layer that is representative of the received bit pattern.

Memory cells are described that include two reference voltages that may store and sense three distinct memory states by compensating for undesired intrinsic charges affecting a memory cell. Although embodiments described herein refer to three memory states, it should be appreciated that in other embodiments, the memory cell may store or sense more than three charge distributions using the described methods and techniques. In a first memory state, a programming voltage or a sensed voltage may be higher than a first reference voltage and a second reference voltage. In a second memory state, the applied voltage or the sensed voltage may be between the first and the second reference voltages. In a third memory state, the applied voltage or the sensed voltage may be lower than the first and the second reference voltages. As such, the memory cell may store and retrieve three memory states.

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.

Memory cells are described that include two reference voltages that may store and sense three distinct memory states by compensating for undesired intrinsic charges affecting a memory cell. Although embodiments described herein refer to three memory states, it should be appreciated that in other embodiments, the memory cell may store or sense more than three charge distributions using the described methods and techniques. In a first memory state, a programming voltage or a sensed voltage may be higher than a first reference voltage and a second reference voltage. In a second memory state, the applied voltage or the sensed voltage may be between the first and the second reference voltages. In a third memory state, the applied voltage or the sensed voltage may be lower than the first and the second reference voltages. As such, the memory cell may store and retrieve three memory states.

Embodiments of this application provide a method and system for adjusting a memory, and a semiconductor device. The method for adjusting a memory includes: acquiring a mapping relationship among a temperature of a transistor, a substrate bias voltage of a sense amplification transistor in a sense amplifier, and an actual data writing time of the memory; acquiring a current temperature of the transistor; and adjusting the substrate bias voltage on the basis of the current temperature and the mapping relationship, such that an actual data writing time corresponding to an adjusted substrate bias voltage is within a preset writing time.

A semiconductor memory device according to an embodiment includes a string, a bit line, a well line, and a sequencer. The string includes first and second select transistors, and memory cell transistors using a ferroelectric material. The bit line and the well line are connected to the first and second select transistors, respectively. At a time in an erase verify operation, the sequencer is configured to apply a first voltage to the memory cell transistors, to apply a second voltage lower than the first voltage to the first select transistor, to apply a third voltage lower than the first voltage to the second select transistor, to apply a fourth voltage to the bit line, and to apply a fifth voltage higher than the fourth voltage to the well line.

A data processing method, a data processing circuit, and a computing apparatus are provided. In the method, data is obtained. A first value of a bit of the data is switched into a. second value according to data distribution and an accessing property of memory. The second value of the bit is stored in the memory in response to switching the bit.

Memory cells are described that include two reference voltages that may store and sense three distinct memory states by compensating for undesired intrinsic charges affecting a memory cell. Although embodiments described herein refer to three memory states, it should be appreciated that in other embodiments, the memory cell may store or sense more than three charge distributions using the described methods and techniques. In a first memory state, a programming voltage or a sensed voltage may be higher than a first reference voltage and a second reference voltage. In a second memory state, the applied voltage or the sensed voltage may be between the first and the second reference voltages. In a third memory state, the applied voltage or the sensed voltage may be lower than the first and the second reference voltages. As such, the memory cell may store and retrieve three memory states.