A method for dynamically estimating interference compensation thresholds of a page of memory includes performing a mock read on a target row using a mock read threshold, performing a read operation on an interference source and reading an interference state of the interference source, computing a histogram and a corresponding threshold based on the mock read threshold and the interference state of the interference source, and estimating a read threshold to dynamically compensate the interference state of the target row based on the histogram.

A storage device includes 3D NAND including layers of multi-level cells. Test reads are performed by reading only LSB pages and reading layers in a repeating pattern of reading two and skipping two. A test read of a block is performed when its read count reaches a threshold. The counter threshold is updated according to errors detected during the test read such that the frequency of test reads increases with increase in errors detected. Counter thresholds according to errors may be specified in a table. The table may be selected as corresponding to a range of PEC values including the current PEC count of the 3D NAND. Each table further specifies a number of errors that will result in garbage collection being performed.

Methods and devices for reading a memory cell using a sense amplifier with split capacitors is described. The sense amplifier may include a first capacitor and a second capacitor that may be configured to provide a larger capacitance during certain portions of a read operation and a lower capacitance during other portions of the read operation. In some cases, the first capacitor and the second capacitor are configured to be coupled in parallel between a signal node and a voltage source during a first portion of the read operation to provide a higher capacitance. The first capacitor may be decoupled from the second capacitor during a second portion of the read operation to provide a lower capacitance during the second portion.

A memory sub-system configured to generate or update a model for reading memory cells in a memory device. For example, in response to a processing device of a memory sub-system transmitting to a memory device read commands that are configured to instruct the memory device to retrieve data from a group of memory cells formed on an integrated circuit die in the memory device, the memory device may measure signal and noise characteristics of the group of memory cells during execution of the read commands. Based on the signal and noise characteristics the memory sub-system can generate or update, measured during the execution of the read commands a model of changes relevant to reading data from the group of memory cells. The changes can be a result of damage, charge loss, read disturb, cross-temperature effect, etc.

An apparatus includes: a semiconductor substrate; an isolation region in the semiconductor substrate, the isolation region including an isolation trench filled with an insulating material therein; a plurality of island-shaped active regions in the semiconductor substrate surrounded by the isolation region; and a buried word-line having a bottom, the buried word-line at least passing across the isolation region between the plurality of active regions; wherein the isolation trench includes upper, middle and lower portions, each of the upper and lower portions has a substantially flat surface and the middle portion has a bulged surface.

This document describes apparatuses and techniques for termination for single-ended (SE) mode operation of a memory device. In various aspects, a termination circuit can terminate an unused signal line of a differential pair to a ground or power rail using a switch element when operating in the SE mode. The termination circuit may also disconnect the unused signal line from a first input of a differential amplifier and connect a reference voltage to the first input of the differential amplifier. Based on the reference voltage, the differential amplifier amplifies an SE signal received using another signal line of the differential pair at a second input of the differential amplifier to provide a clock signal for memory operations. Thus, the termination circuit may reduce an amount by which noise associated with the unused signal line affects the differential amplifier when the memory device operates in SE mode.

Si pillars 22a to 22d stand on an N.sup.+ layer 21 connected to a source line SL. Lower portions of the Si pillars 22a to 22d are surrounded by a HfO.sub.2 layer 25a, which is surrounded by TiN layers 26a and 26b that are respectively connected to plate lines PL1 and PL2 and are isolated from each other. Upper portions of the Si pillars 22a to 22d are surrounded by a HfO.sub.2 layer 25b, which is surrounded by TiN layers 28a and 28b that are respectively connected to word lines WL1 and WL2 and are isolated from each other. A thickness Lg1 of the TiN layer 26a on a line X-X′ is smaller than twice a thickness Lg2 of the TiN layer 26a on a line Y-Y′ and is larger than or equal to the thickness Lg2. The thickness Lg1 of the TiN layer 28a on the line X-X′ is smaller than twice the thickness Lg2 of the TiN layer 28a on the line Y-Y′.

A memory apparatus includes pages each including a plurality of memory cells arranged in a column on a substrate. A voltage applied to each of a first gate conductor layer, a second gate conductor layer, a first impurity layer, and a second impurity layer in each memory cell included in each page is controlled to perform a page write operation for retaining holes, which have been formed through an impact ionization phenomenon or using a gate induced drain leakage current, in a channel semiconductor layer, or a voltage applied to each of the first gate conductor layer, the second gate conductor layer, a third gate conductor layer, a fourth gate conductor layer, the first impurity layer, and the second impurity layer is controlled to perform a page erase operation for removing the holes from the channel semiconductor layer. The first impurity layer in the memory cell connects to a source line. The second impurity layer connects to a bit line. One of the first gate conductor layer and the second gate conductor layer connects to a word line, and the other connects to a first drive control line. The bit line connects to a sense amplifier circuit via a switch circuit. During a page read operation, page data in a group of memory cells selected by the word line is read by the sense amplifier circuit. During each of the page write operation, the page erase operation, and the page read operation, an identical fixed voltage is applied to the first drive control line.

Embodiments provide a data sampling circuit and a data sampling device. The sampling circuit includes: a first sampling module configured to respond to a signal from a data signal terminal and a signal from a reference signal terminal and to act on a first node and a second node; a second sampling module configured to respond to a signal from the first node and a signal from the second node and to act on a third node and a fourth node; a latch module configured to input a high level signal to a first output terminal and input a low level signal to a second output terminal or input the low level signal to the first output terminal and input the high level signal to the second output terminal according to a signal from the third node and a signal from the fourth node; and a decision feedback equalization module.

A row hammer control method and a memory device are provided. The memory device monitors the row hammer address(es) having the number of accesses equal to or more than a predetermined number of times or having a higher number of accesses as compared with other access addresses during the first row hammer monitoring time frame and malicious row hammer address(es) accessed at random sampling time points during the second row hammer monitoring time frame and being the same as the row hammer address(es), notifies a memory controller of the malicious row hammer address(es) when the number of malicious row hammer addresses exceeds a threshold value, and causes a target refresh a memory cell row physically adjacent to a memory cell row corresponding to the malicious row hammer address(es) to be performed.