A floating-node memory device includes a metal-oxide-semiconductor (MOS) transistor including a first polysilicon gate, a source region, and a drain region in a first well region, a tunneling device including a second polysilicon gate in a second well region, and a metal-insulator-metal (MIM) capacitor including a conductive top plate and a bottom plate formed in a metal interconnect layer. The floating-node device includes a floating-node comprising the first polysilicon gate, the second polysilicon gate, and the conductive top plate of the MIM capacitor coupled together, a control node at the bottom plate of the MIM capacitor, an erase node in the second well region, a source node at the source region of the MOS transistor, and a drain node at the drain region of the MOS transistor.

A non-volatile memory device includes a floating-node memory cell disposed in an integrated circuit (IC). The memory cell includes a floating-node, a control node, an erase node, a source node, and a drain node. The memory device also includes a high-voltage input node for coupling to an external programmable high-voltage source external to the IC. The memory device also includes a high-voltage switch circuit coupled to the high-voltage input node for providing a voltage signal for performing hot-electron programming of charges to the floating node and tunneling erase of charges from the floating node.

Various examples described herein are directed to systems and methods for generating data values using a NAND flash array. A memory controller may read a number of memory cells at the NAND flash array using an initial read level to generate a first raw string. The memory controller may determine that a difference between a number of bits from the first raw string having a value of logical zero and a number of bits from the first raw string having a value of logical one is greater than a threshold value and read the number of memory cells using a second read level to generate a second raw string. The memory controller may determine that a difference between a number of bits from the second raw string having a value of logical zero and a number of bits from the second raw string having a value of logical one is not greater than a threshold value and applying a cryptographic function using the second raw string to generate a first PUF value.

A memory apparatus and method of operation is provided. The apparatus includes memory cells connected to word lines and bit lines and arranged in strings and configured to retain a threshold voltage. Each of the memory cells is configured to be erased in an erase operation occurring during an erase time period. A control circuit is configured to adjust at least a portion of the erase time period in response to determining the erase operation is a segmented erase operation and is resumed after being suspended. The control circuit applies an erase signal having a plurality of voltage segments temporally separated from one another during the erase time period to each of the strings while simultaneously applying a word line erase voltage to selected ones of the word lines to encourage erasing of the memory cells coupled to the selected ones of the word lines in the segmented erase operation.

A memory device includes a cell area including memory blocks, and a peripheral circuit area including peripheral circuits that execute an erase operation for each of the memory blocks. Each memory block includes word lines that are stacked on a substrate, channel structures penetrate through the word lines, and a source region that is disposed on the substrate and connected to the channel structures. During the erase operation in which an erase voltage is provided to the source region of a target memory block among the memory blocks, the peripheral circuits reduce a voltage of a first word line from a first bias voltage to a second bias voltage at a first time, and to reduce a voltage of a second word line, different from the first word line, from a third bias voltage to a fourth bias voltage at a second time different from the first time.

A memory system includes a nonvolatile memory which comprises a plurality of memory cells capable of storing 4-bit data represented by first to fourth bits by sixteen threshold regions, and a memory controller configured to cause the nonvolatile memory to execute a first program for writing data of the first bit, the second bit, and the fourth bit and then causes the nonvolatile memory to execute a second program for writing data of the third bit. In fifteen boundaries existing between adjacent threshold regions among the first to sixteenth threshold regions, a maximum value of the number of first boundaries used for determining a value of the data of the first bit, the number of second boundaries used for determining a value of the data of the second bit, the number of third boundaries used for determining a value of the data of the third bit.

A method of erasing memory cells in a memory device is provided. The method includes grouping a plurality of word lines into a first group, which does not include edge word lines, and a second group, which does include edge word lines. An erase operation is performed on the memory cells of the first and second groups until erase-verify of the memory cells of the first group passes. It is then determined if further erase of the memory cells of the second group is necessary. In response to it being determined that the additional erase operation is necessary, an additional erase operation is performed on at least some of the memory cells of the second group until erase-verify of the memory cells of the second group passes.

A non-volatile memory device and a non-volatile memory erasing operation method is provided. The method includes the following. A first erasing operation is performed, including reducing a threshold voltage of each of a plurality of memory cells of the non-volatile memory through a first erasing pulse. A first verification operation is performed to confirm whether the threshold voltage of each of the memory cells is less than an erasing target voltage level. In response to at least one of the memory cells failing the first verification operation, a second erasing operation is performed. The second erasing operation includes selecting the at least one memory cell failing the first verification operation, and reducing the threshold voltage of the at least one memory cell to be less than the erasing target voltage level through a second erasing pulse.

Disclosed is an operation method of a memory device that includes a plurality of memory cells stacked in a direction perpendicular to a substrate. The method includes performing first to (n−1)-th program loops on selected memory cells connected to a selected word line from among the plurality of memory cells, based on a first program parameter, and after the (n−1)-th program loop is performed, performing n-th to k-th program loops on the selected memory cells, based on a second program parameter different from the first program parameter. Herein, n is an integer greater than 1 and k is an integer greater than or equal to n. The first and second program parameters include information about at least two of a program voltage increment, a 2-step verify range, and a bit line forcing voltage used in the first to k-th program loops.

Control logic in a memory device initiates an erase operation on a memory array and causes an erase voltage signal to be applied to a source terminal of a string of memory cells in a data block of the memory array during the erase operation. The control logic further causes a first voltage signal to be applied to a first select line of the data block and a second voltage signal to be applied to a second select line of the data block, wherein the first select line is coupled to a first device in the string of memory cells and the second select line is coupled to a second device in the string of memory cells, and wherein the first voltage signal and the second voltage signal both have a common first voltage offset with respect to the erase voltage signal during a first stage of the erase operation. The control logic further determines an end of the first stage of the erase operation and causes the first voltage signal to decrease to a second voltage offset with respect to the erase voltage signal and causes the second voltage signal to decrease to a third voltage offset with respect to the erase voltage signal during a second stage of the erase operation, wherein the second offset is greater than the third offset.