Abstract: A programming method and memory structure for preventing punch-through in a short channel source-side select gate structure includes adjusting voltages on the selected and unselected bitlines, and the program, pass, and select gate voltages.

Abstract: A system and apparatus for adjusting threshold program and erase voltages in a memory array, such as a floating gate memory array, for example. One such method includes applying a first voltage level to a first edge word line of a memory block string and applying a second voltage level to a second edge word line of the memory block string. Such a method might also include applying a third voltage level to non-edge word lines of the memory block string.

Abstract: A programming method of a non-volatile memory device that includes a string of memory cells with a plurality of floating gates and a plurality of control gates disposed alternately, wherein each of the memory cells includes one floating gate and two control gates disposed adjacent to the floating gate and two neighboring memory cells share one control gate. The programming method includes applying a first program voltage to a first control gate of a selected memory cell and a second program voltage that is higher than the first program voltage to a second control gate of the selected memory cell, and applying a first pass voltage to a third control gate disposed adjacent to the first control gate and a second pass voltage that is lower than the first pass voltage to a fourth control gate disposed adjacent to the second control gate.

Abstract: A method of operating a semiconductor memory device includes performing a first program operation in order to raise threshold voltages of memory cells, performing a program verification operation for detecting fast program memory cells, each having a threshold voltage risen higher than a first sub-verification voltage from a second sub-verification voltage or lower, by using a target verification voltage and the first sub-verification voltage and the second sub-verification voltage which are sequentially lower than the target verification voltage, and performing a second program operation under a condition that an increment of each of threshold voltages of memory cells, which is lower than the target verification voltage, is greater than an increment of the threshold voltage of each of the fast program memory cells.

Abstract: In a non-volatile semiconductor memory device and a method for manufacturing the device, each memory cell and its select Tr have the same gate insulating film as a Vcc Tr. Further, the gate electrodes of a Vpp Tr and Vcc Tr are realized by the use of a first polysilicon layer. A material such as salicide or a metal, which differs from second polysilicon (which forms a control gate layer), may be provided on the first polysilicon layer. With the above features, a non-volatile semiconductor memory device can be manufactured by reduced steps and be operated at high speed in a reliable manner.

Abstract: A memory device includes a first bit line coupled to a first source/drain region of a first multiplexer gate, a second bit line coupled to a first source/drain region of a second multiplexer gate, and a sensing device having an input coupled to a second source/drain region of the first multiplexer gate and a second source/drain region of the second multiplexer gate. The input of the sensing device is formed at a vertical level that is different than a vertical level at which at least one of the first and second bit lines is formed.

Abstract: A method of operating a semiconductor device includes programming selected memory cells by supplying a selected word line with a program voltage which increases and supplying the remaining unselected word lines with a first pass voltage which is substantially constant; and programming the selected memory cells while supplying first unselected word lines adjacent to the selected word line with a second pass voltage increasing in proportion to the program voltage, when a difference between the program voltage and the first pass voltage reaches a critical voltage difference.

Abstract: A reading method of a non-volatile memory device that includes a plurality memory cells that each include one floating gate and two control gates disposed adjacent to the floating gate on two alternate sides of the floating gate, respectively, and two adjacent memory cells share one control gate, the reading method comprising applying a read voltage to control gates of a selected memory cell, applying a second pass voltage to alternate control gates of the memory cells different from the control gates of the selected memory cells starting from the control gates next to the selected memory cell, and applying a first pass voltage that is lower than the second pass voltage to alternate the control gates of the memory cells different from the control gates of the selected memory cells starting from the control gates secondly next to the selected memory cell.

Abstract: A method for program verify is disclosed, such as one in which a threshold voltage of a memory cell that has been biased with a programming voltage can be determined and its relationship with multiple program verify voltage ranges can be determined. The program verify voltage range in which the threshold voltage is located determines the subsequent bit line voltage. The subsequent bit line voltage may be less than a previous bit line voltage used to program the memory cell.

Abstract: A semiconductor memory device capable of preventing a defect caused by lowering the etching precision in an end area of the memory cell array is provided. A first block is constructed by first memory cell units each having of memory cells, a second block is constructed by second memory cell units each having memory cells, and the memory cell array is constructed by arranging the first blocks on both end portions thereof and arranging the second blocks on other portions thereof. The structure of the first memory cell unit on the end side of the memory cell array is different from the second memory cell unit. Wirings for connecting the selection gate lines of the memory cell array to corresponding transistors in a row decoder are formed of wiring layers formed above wirings for connecting control gate lines of the memory cell array to the transistors in the row decoder.

Abstract: An operating method of a semiconductor memory device includes erasing all memory cells of a selected cell block, performing a soft program operation on the erased memory cells by supplying a soft program pulse to word lines of the selected cell block, performing a first verify operation using a first voltage level lower than a target voltage level of the soft program operation, performing a second verify operation using the target voltage level, setting voltages of bit lines, and repeating the soft program operation, the first verify operation, the second verify operation, and an operation of setting the voltages of bit lines while raising the soft program pulse gradually.

Abstract: A programming method of a nonvolatile memory device includes inputting even data and odd data to be programmed into even memory cells coupled to even bit lines and odd memory cells coupled to odd bit lines, respectively, setting a sense signal as a first sense signal or a second sense signal having a lower voltage level than the first sense signal, based on odd data of odd memory cells adjacent to each of the even memory cells to be programmed, programming the even data into the even memory cells by supplying a program voltage, performing a program verify operation on each of the even memory cells in response to the set sense signal, and programming the odd data into the odd memory cells by supplying a program voltage.

Abstract: Disclosed is a method of forming memory devices employing halogen ion implantation and diffusion processes. In one illustrative embodiment, the method includes forming a plurality of word line structures above a semiconducting substrate, each of the word line structures comprising a gate insulation layer, performing an LDD ion implantation process to form LDD doped regions in the substrate between the word line structures, performing a halogen ion implantation process to implant atoms of halogen into the semiconducting substrate between the word line structures, and performing at least one anneal process to cause at least some of the atoms of halogen to diffuse into the gate insulation layers on adjacent word line structures.

Abstract: A system and apparatus for adjusting threshold program and erase voltages in a memory array, such as a floating gate memory array, for example. One such method includes applying a first voltage level to a first edge word line of a memory block string and applying a second voltage level to a second edge word line of the memory block string. Such a method might also include applying a third voltage level to non-edge word lines of the memory block string.

Abstract: A transistor construction includes a first floating gate having a first conductive or semiconductive surface and a second floating gate having a second conductive or semiconductive surface. A dielectric region is circumferentially surrounded by the first surface. The region is configured to reduce capacitive coupling between the first and second surfaces. Another transistor construction includes a floating gate having a cavity extending completely through the floating gate from a first surface of the floating gate to an opposing second surface of the floating gate. The floating gate otherwise encloses the cavity, which is filled with at least one dielectric. A method includes closing an upper portion of an opening in insulator material with a gate material during the deposition before filling a lower portion with the gate material. The depositing and closing provide an enclosed cavity within the lower portion of the opening.

Abstract: Memory devices and methods for operating a memory cell are disclosed, such as a method that uses two program verify levels (e.g., low program verify level and program verify level) to determine how a data line voltage should be increased. A threshold voltage of a memory cell that has been biased with a programming voltage is determined and its relationship with the two program verify levels is determined. If the threshold voltage is less than the low program verify level, the data line can be biased at a ground voltage (e.g., 0V) for a subsequent programming pulse. If the threshold voltage is greater than the program verify level, the data line can be biased at an inhibit voltage for a subsequent programming pulse. If the threshold voltage is between the two program verify levels, the data line voltage can be increased for each subsequent programming pulse in which the threshold voltage is between the two program verify levels.

Abstract: A vertical channel type non-volatile memory device having a plurality of memory cells stacked along a channel includes the channel configured to be protruded from a substrate, a tunnel insulation layer configured to surround the channel, a plurality of floating gate electrodes and a plurality of control gate electrodes configured to be alternately stacked along the channel, and a charge blocking layer interposed between the plurality of the floating gate electrodes and the plurality of the control gate electrodes alternately stacked.

Abstract: The present disclosure includes methods, devices, modules, and systems for operating non-volatile multilevel memory cells. One method embodiment includes assigning, to a first cell coupled to a row select line, a first number of program states to which the first cell can be programmed. The method includes assigning, to a second cell coupled to the row select line, a second number of program states to which the second cell can be programmed, wherein the second number of program states is greater than the first number of program states. The method includes programming the first cell to one of the first number of program states prior to programming the second cell to one of the second number of program states.

Abstract: Disclosed is a method of forming memory devices employing halogen ion implantation and diffusion processes. In one illustrative embodiment, the method includes forming a plurality of word line structures above a semiconducting substrate, each of the word line structures comprising a gate insulation layer, performing an LDD ion implantation process to form LDD doped regions in the substrate between the word line structures, performing a halogen ion implantation process to implant atoms of halogen into the semiconducting substrate between the word line structures, and performing at least one anneal process to cause at least some of the atoms of halogen to diffuse into the gate insulation layers on adjacent word line structures.

Abstract: A semiconductor device includes vertical channel layers, control gates and interlayer insulating layers stacked alternately with each other on the substrate and surrounding the vertical channel layers, floating gates interposed between the vertical channel layers and the control gates and separated from each other by the interlayer insulating layers, and charge blocking layers interposed between the floating gates and the control gates.