Abstract: A three-dimensional monolithic memory device includes at least one device region and a plurality of contact regions each including a stack of an alternating plurality of conductive word line contact layers and insulating layers located over a substrate, where the stacks in the plurality of contact regions are separated from one another by an insulating material, and a bridge connector including a conductive material extending between a first conductive word line contact layer of a first stack in a first contact region and a second conductive word line contact layer of a second stack in a second contact region, where the first word line contact layer extends in a first contact level substantially parallel to a major surface of the substrate and the second word line contact layer extends in a second contact level substantially parallel to the major surface of the substrate that is different than the first level.

Abstract: A semiconductor device includes a stacked structure including conductive layers and insulating layers stacked alternately with each other, first semiconductor patterns passing through the stacked structure and arranged in a first direction, second semiconductor patterns passing through the stacked structure and arranged in the first direction, wherein the second semiconductor patterns are adjacent to the first semiconductor patterns in a second direction crossing the first direction, air gaps located between the first semiconductor patterns and the second semiconductor patterns and extending in the first direction, and at least one blocking pattern passing through the stacked structure and filling portions of the air gaps.

Abstract: A method of forming a three-dimensional memory device includes forming a stack of alternating first and second material layers over a substrate, forming a memory opening through the stack, forming a memory film and a semiconductor channel in the memory opening, and forming backside recesses by removing the second material layers selective to the first material layers and the memory film, where an outer sidewall of the memory film is physically exposed within each backside recess. The method also includes forming at least one set of surfaces selected from silicon deposition inhibiting surfaces on the first material layers and silicon deposition promoting surfaces over the memory film in the back side recesses, selectively growing a silicon-containing semiconductor portion laterally within each backside recess, forming at least one blocking dielectric within the backside recesses, and forming conductive material layers by depositing a conductive material within the backside recesses.

Abstract: A method includes providing a semiconductor structure including a nonvolatile memory cell element and one or more electrically insulating layers covering the nonvolatile memory cell element. The nonvolatile memory cell element includes a source region, a channel region, a drain region and a floating gate over at least a first portion of the channel region. A first opening is formed in the electrically insulating layers over the floating gate, a control gate insulation layer is deposited, and a second opening is formed in the electrically insulating layers over the drain region. The first opening and the second opening are filled with an electrically conductive material. The electrically conductive material in the first opening provides a control gate of the nonvolatile memory cell element and the electrically conductive material in the second opening provides an electrical contact to the drain region.

Abstract: In a semiconductor device, a first gate structure is provided in a cell transistor region and includes a floating gate electrode, a first dielectric layer pattern, and a control gate electrode including a first metal silicide pattern. A second gate structure is provided in a selecting transistor region and includes a first conductive layer pattern, a second dielectric layer pattern, and a first gate electrode including a second metal silicide pattern. A third gate structure is provided in a peripheral circuit region and includes a second conductive layer pattern, a third dielectric layer pattern including opening portions on the second conductive layer pattern, and a second gate electrode including a concavo-convex portion at an upper surface portion thereof and a third metal silicide pattern. The third metal silicide pattern has a uniform thickness.

Abstract: A novel MOS transistor, which includes a source region, a drain region, a channel region, an isolation region, a drift region, a gate dielectric layer, a gate electrode and a field plate, is provided. The gate electrode has a first portion and a second portion. The first portion of a first conductivity type is located over the channel region and has a width equal to or greater than a distance of the gate electrode overlapped with the channel region. The second portion is un-doped and located over the isolation region. Accordingly, the MOS transistor allows higher process freedom saves production cost, as well as improves reliability.

Abstract: A select gate transistor for a NAND device includes a select gate electrode having a first side, a second side, and top and a bottom, a semiconductor channel located adjacent to the first side, the second side and the bottom of the select gate electrode, and a gate insulating layer located between the channel and the first side, the second side and the bottom of the select gate electrode.

Abstract: A NAND flash memory includes a select transistor having a first region formed of a stack of layers on the substrate surface, and a second region that includes an opening through an interpoly dielectric layer, floating gate layer, and tunnel dielectric layer, the opening separated from the substrate surface by a select gate dielectric on the substrate surface, the opening filled by a control gate layer.

Abstract: A semiconductor device may include pillars and a plurality of conductive layers being stacked while surrounding the pillars and including a plurality of first regions including non-conductive material layers and a plurality of second regions including conductive material layers, wherein the first regions and the second regions are alternately arranged.

Abstract: An integrated circuit includes blocks and global lines overlying the blocks. The blocks include a plurality of levels including two dimensional arrays of memory cells having horizontal lines and being intersected by vertical lines coupled to corresponding memory cells. Levels include contact pads communicating with horizontal lines for a given block. The global lines include connectors. Connectors coupled to given global lines are coupled to landing areas on corresponding contact pads of the blocks. The blocks include first and second blocks disposed so that a first set of the contact pads associated with the first block are next to a second set of contact pads associated with the second block. The landing areas of the contact pads of the first and second blocks are mirror image surfaces of one another. The horizontal lines can be bit lines and the vertical lines can be word lines.

Abstract: Lateral power devices where immobile electrostatic charge is emplaced in dielectric material adjoining the drift region. A shield gate is interposed between the gate electrode and the drain, to reduce the Miller charge. In some embodiments the gate electrode is a trench gate, and in such cases the shield electrode too is preferably vertically extended.

Abstract: A memory device includes a plurality of stacks of alternating active strips and insulating strips. The insulating strips have effective oxide thicknesses (EOT) so that the stacks have non-simple spatial periods on a line through the alternating active strips and insulating strips. A plurality of conductive lines are arranged orthogonally over, and have surfaces conformal with, the plurality of stacks, defining a multi-layer array of interface regions at cross-points between side surfaces of the active strips in the stacks and the conductive lines. Memory elements are disposed in the interface regions, which establish a 3D array of memory cells accessible via the plurality of active strips and the plurality of conductive lines. The insulating strips in the stacks can include a first group of strips having a first EOT and a second group of strips having a second EOT that is greater than the first EOT.

Abstract: A method of making a monolithic three dimensional NAND string including forming a stack of alternating layers of a first material and a second material different from the first material over a substrate, forming an at least one opening in the stack, forming at least a portion of a memory film in the at least one opening and forming a first portion of a semiconductor channel followed by forming a second portion of the semiconductor channel in the at least one opening. The second portion of the semiconductor channel comprises silicon and germanium and contains more germanium than a first portion of the semiconductor channel which is located closer to the memory film than the second portion.

Abstract: Methods of fabricating a semiconductor device are provided. The method includes alternately stacking first material layers and second material layers on a substrate to form a stacked structure, forming a through hole penetrating the stacked structure, forming a data storage layer on a sidewall of the through hole, forming a semiconductor pattern electrically connected to the substrate on an inner sidewall of the data storage layer, etching an upper portion of the data storage layer to form a first recessed region exposing an outer sidewall of the semiconductor pattern, and forming a first conductive layer in the first recessed region. Related devices are also disclosed.

Abstract: Some embodiments include a method of fabricating integrated structures. A metal-containing material is formed over a stack of alternating first and second levels. An opening is formed through the metal-containing material and the stack. Repeating vertically-stacked electrical components are formed along the stack at sidewalls of the opening. Some embodiments include a method of forming vertically-stacked memory cells. Metal-containing material is formed over a stack of alternating silicon dioxide levels and conductively-doped silicon levels. A first opening is formed through the metal-containing material and the stack. Cavities are formed to extend into the conductively-doped silicon levels along sidewalls of the first opening. Charge-blocking dielectric and charge-storage structures are formed within the cavities to leave a second opening. Sidewalls of the second opening are lined with gate dielectric and then channel material is formed within the second opening.

Abstract: A semiconductor memory device according to an embodiment includes a semiconductor substrate, a first insulating film provided on the semiconductor substrate, a plurality of first electrodes provided on the first insulating film, a second insulating film provided on a side surface of the first electrodes and on an upper surface of the first electrodes, and a second electrode insulated from the first electrodes by the second insulating film. The second electrode includes an interconnect portion provided on the second insulating film, and a downward-extending portion extending into a space between the first electrodes from the interconnect portion. A lower end portion of the downward-extending portion is not covered with the second insulating film.

Abstract: A semiconductor memory device includes a pipe channel layer formed on a semiconductor substrate, a first channel layer, a second channel layer and a third channel layer, connected with the pipe channel layer, first conductive layers stacked while surrounding the first channel layer, second conductive layers stacked while surrounding the second channel layer, and third conductive layers stacked while surrounding the third channel layer, wherein the first to third conductive layers are separately controlled.

Abstract: Methods of forming multi-tiered semiconductor devices are described, along with apparatus and systems that include them. In one such method, an opening is formed in a tier of semiconductor material and a tier of dielectric. A portion of the tier of semiconductor material exposed by the opening is processed so that the portion is doped differently than the remaining semiconductor material in the tier. At least substantially all of the remaining semiconductor material of the tier is removed, leaving the differently doped portion of the tier of semiconductor material as a charge storage structure. A tunneling dielectric is formed on a first surface of the charge storage structure and an intergate dielectric is formed on a second surface of the charge storage structure. Additional embodiments are also described.

Abstract: A monolithic three dimensional NAND string includes a semiconductor channel, with at least one end portion of the semiconductor channel extending substantially perpendicular to a major surface of a substrate, and a plurality of copper containing control gate electrodes extending substantially parallel to the major surface of the substrate. The plurality of control gate electrodes include at least a first control gate electrode located in a first device level and a second control gate electrode located in a second device level located over the major surface of the substrate and below the first device level. The NAND string also includes a blocking dielectric located over the plurality of control gates, a tunnel dielectric in contact with the semiconductor channel, and at least one charge storage region located between the blocking dielectric and the tunnel dielectric.

Abstract: A semiconductor device and a method of manufacturing the same. The semiconductor device includes a channel, a gate, and a memory layer is interposed between the channel and the gate. The memory layer includes a tunnel insulating layer adjacent to the channel, a charge blocking layer adjacent to the gate, and a charge storing layer interposed between the tunnel insulating layer and the charge blocking layer. The tunnel insulating layer includes a first insulating layer adjacent to the channel and an air layer interposed between the first insulating layer and the charge storing layer.

Abstract: Provided is a semiconductor device including a pillar, a gate electrode having a first conductive pattern surrounding the pillar and a plurality of second conductive patterns which protrude from the first conductive pattern and are arranged to be spaced apart from each other, and an insulating pattern interposed between the pillar and the first conductive pattern.

Abstract: A semiconductor memory device and a method of manufacturing the same are provided. The device includes interlayer insulating patterns and conductive patterns stacked alternately, vertical channel layers formed through the interlayer insulating patterns and the conductive patterns, a tunnel insulating layer formed to surround sidewalls of each of the vertical channel layers, and a multifunctional layer formed to surround the tunnel insulating layer. The multifunctional layer includes trap regions disposed at intersections between the vertical channel layers and the conductive patterns, respectively, and disposed to be in contact with the tunnel insulating layer, blocking regions disposed to be in contact with the trap regions and the conductive patterns, and sacrificial regions disposed between adjacent ones of the blocking regions.

Abstract: A semiconductor device including a first isolation region dividing a semiconductor substrate into first regions; memory cells each including a tunnel insulating film, a charge storing layer, an interelectrode insulating film, and a control gate electrode above the first region; a second isolation region dividing the substrate into second regions in a peripheral circuit region; and a peripheral circuit transistor including a gate insulating film and a gate electrode above the second region. The first isolation region includes a first trench, a first element isolation insulating film filled in a bottom portion of the first trench, and a first gap formed between the first element isolation insulating film and the interelectrode insulating film. The second isolation region includes a second trench and a second element isolation insulating film filled in the second trench. The first and the second element isolation insulating films have different properties.

Abstract: According to one embodiment, a nonvolatile semiconductor memory device comprises a semiconductor substrate, a first layer formed above the semiconductor substrate, a first conductive layer, an inter-electrode insulating layer, and a second conductive layer sequentially stacked above the first layer, a memory film formed on an inner surface of each of a pair of through holes provided in the first conductive layer, the inter-electrode insulating layer, and the second conductive layer and extending in a stacking direction, a semiconductor layer formed on the memory film in the pair of through holes, and a metal layer formed in part of the pair of through holes and/or in part of a connection hole that is provided in the first layer and connects lower end portions of the pair of through holes, the metal layer being in contact with the semiconductor layer.

Abstract: Methods for forming a string of memory cells and apparatuses having a vertical string of memory cells are disclosed. One such string of memory cells can be formed at least partially in a stack of materials comprising a plurality of alternating levels of control gate material and insulator material. A memory cell of the string can include floating gate material adjacent to a level of control gate material of the levels of control gate material. The memory cell can also include tunnel dielectric material adjacent to the floating gate material. The level of control gate material and the tunnel dielectric material are adjacent opposing surfaces of the floating gate material. The memory cell can include metal along an interface between the tunnel dielectric material and the floating gate material. The memory cell can further include a semiconductor material adjacent to the tunnel dielectric material.

Abstract: A semiconductor device, includes: a semiconductor substrate; a first conductivity type well and a second conductivity type well; a first active area; a second active area; a first well contact layer; a plurality of first source/drain layers; a first gate insulating film; a first gate electrode; a second well contact layer; a plurality of second source/drain layers; a second gate insulating film; and a second gate electrode. The first well contact layer is formed in the first active area at one end part in the one direction. The one end parts in each of the first active areas and in each of the second active areas are mutually on the same side.

Abstract: A memory device, and method of make same, having a substrate of semiconductor material of a first conductivity type, first and second spaced-apart regions in the substrate of a second conductivity type, with a channel region in the substrate therebetween, a conductive floating gate over and insulated from the substrate, wherein the floating gate is disposed at least partially over the first region and a first portion of the channel region, a conductive second gate laterally adjacent to and insulated from the floating gate, wherein the second gate is disposed at least partially over and insulated from a second portion of the channel region, and a stressor region of embedded silicon carbide formed in the substrate underneath the second gate.

Abstract: Provided is an OTP memory cell including a first antifuse unit, a second antifuse unit, a select transistor, and a well region. The first and the second antifuse unit respectively include an antifuse layer and an antifuse gate disposed on a substrate in sequence. The select transistor includes a select gate, a gate dielectric layer, a first doped region, and a second doped region. The select gate is disposed on the substrate. The gate dielectric layer is disposed between the select gate and the substrate. The first and the second doped region are respectively disposed in the substrate at two sides of the select gate, wherein the second doped region is disposed in the substrate at the periphery of the first and the second antifuse unit. The well region is disposed in the substrate below the first and the second antifuse unit and is connected to the second doped region.

Abstract: Example embodiments relate to a three-dimensional semiconductor memory device including an electrode structure on a substrate, the electrode structure including at least one conductive pattern on a lower electrode, and a semiconductor pattern extending through the electrode structure to the substrate. A vertical insulating layer may be between the semiconductor pattern and the electrode structure, and a lower insulating layer may be between the lower electrode and the substrate. The lower insulating layer may be between a bottom surface of the vertical insulating layer and a top surface of the substrate. Example embodiments related to methods for fabricating the foregoing three-dimensional semiconductor memory device.

Abstract: A semiconductor memory device includes a substrate including a cell region and a peripheral region, word lines on the substrate of the cell region, each of the word lines including a charge storing part and a control gate electrode sequentially stacked, and a peripheral gate pattern on the substrate of the peripheral region. Each of the control gate electrode and the peripheral gate pattern includes a high-carbon semiconductor pattern and a low-carbon semiconductor pattern, the low-carbon semiconductor pattern being on the high-carbon semiconductor pattern.

Abstract: Nonvolatile memory devices according to embodiments of the invention include highly integrated vertical stacks of nonvolatile memory cells. These vertical stacks of memory cells can utilize dummy memory cells to compensate for process artifacts that would otherwise yield relatively poor functioning memory cell strings when relatively large numbers of memory cells are stacked vertically on a semiconductor substrate using a plurality of vertical sub-strings electrically connected in series.

Abstract: Methods for forming semiconductor structures are disclosed, including a method that involves forming sets of conductive material and insulating material, forming a first mask over the sets, forming a first number of contact regions, forming a second mask over a first region of the sets, and removing material from of the sets in a second, exposed region laterally adjacent the first region to form a second number of contact regions. Another method includes forming first and second contact regions on portions of sets of conductive materials and insulating materials, each of the second contact regions more proximal to an underlying substrate than each of the first contact regions. Apparatuses such as memory devices including laterally adjacent first and second regions each of which including contact regions of a different portion of a plurality of conductive materials and related methods of forming such devices are also disclosed.

Abstract: A nonvolatile memory device includes a unit cell with a transistor and a capacitor. The transistor is disposed on a substrate having a tunneling region and a channel region and includes a floating gate crossing both the tunneling region and the channel region. The capacitor is coupled to the floating gate.

Abstract: The present application discloses a non-volatile memory device, comprising a semiconductor fin on an insulating layer; a channel region at a central portion of the semiconductor fin; source/drain regions on both sides of the semiconductor fin; a floating gate arranged at a first side of the semiconductor fin and extending in a direction further away from the semiconductor fin; and a first control gate arranged on top of the floating gate or covering top and sidewall portions of the floating gate. The non-volatile memory device reduces a short channel effect, has an increased memory density, and is cost effective.

Abstract: A semiconductor device includes conductive layers and interlayer insulating layers stacked alternately with each other, at least one first channel layer passing through the conductive layers and the interlayer insulating layers, at least one second channel layer coupled to the first channel layers and passing through the conductive layers and the interlayer insulating layers, a first insulating layer interposed between the at least one first channel layer and the conductive layers, and a second insulating layer interposed between the at least one second channel layer and the conductive layers and having a higher nitrogen concentration than the first insulating layer.

Abstract: In accordance with an embodiment, a semiconductor memory device includes a substrate with a semiconductor layer and memory cells on the semiconductor layer. Each memory cell includes a laminated body on the semiconductor layer, a gate insulating film on the laminated body, and a control gate on the gate insulating film. The laminated body includes a tunnel insulating film and a floating gate subsequently laminated in a direction vertical to a front surface of the substrate for N (a natural number equal to or above 2) times. A dimension of a top face of any floating gate in a second or subsequent layer is smaller than a dimension of a bottom surface of the floating gate in the lowermost layer in at least one of a first direction parallel to the front surface of the substrate and a second direction crossing the first direction.

Abstract: According to one embodiment, a memory cell string stacked body includes first memory cell transistors above a semiconductor substrate, and second memory cell transistors below a first channel semiconductor film, and one of the first memory cell transistors and one of the second memory cell transistors share with a control gate electrode. The control gate electrodes of the first memory cell transistors cover an upper surface of a first charge storage layer and at least a part of a side surface in a second direction via a first insulating film in the one of the first memory cell transistors. The control gate electrodes of the second memory cell transistors cover only a lower surface of a second charge storage layer via a second insulating film in one of the second memory cell transistors.

Abstract: A memory cell, a memory array and an operation method are disclosed herein. The memory cell includes a substrate with a first conductivity type, a first doped region with a second conductivity type, a second doped region with the second conductivity type, a first floating gate, a second floating gate and a word gate. The first and the second doped region are disposed in the substrate. The first floating gate is disposed on the substrate and electrically coupled to the first doped region. The second floating gate is disposed on the substrate and electrically coupled to the second doped region. The word line gate is disposed on the substrate and between the first and second doped region, wherein the word gate includes a first part extending over the first floating gate and a second part extending over the second floating gate.

Abstract: High-density semiconductor memory is provided with enhancements to gate-coupling and electrical isolation between discrete devices in non-volatile memory. The intermediate dielectric between control gates and charge storage regions is varied in the row direction, with different dielectric constants for the varied materials to provide adequate inter-gate coupling while protecting from fringing fields and parasitic capacitances. Electrical isolation is further provided, at least in part, by air gaps that are formed in the column (bit line) direction and/or air gaps that are formed in the row (word line) direction.

Abstract: A device having a substrate prepared with a memory cell region having a memory cell is disclosed. The memory cell includes an access transistor and a storage transistor. The access transistor includes first and second source/drain (S/D) regions and the storage transistor includes first and second storage S/D regions. The access and storage transistors are coupled in series and the second S/D regions being a common S/D region. An erase gate is disposed over the common S/D region. A program gate is disposed over the first storage S/D region. Such an arrangement of the memory cell decouples a program channel and an erase channel.

Abstract: A device having thin-film transistor (TFT) floating gate memory cell structures is provided. The device includes a substrate, a dielectric layer on the substrate, and one or more source or drain regions being embedded in the dielectric layer. the dielectric layer being associated with a first surface. Each of the one or more source or drain regions includes an N+ polysilicon layer on a diffusion barrier layer which is on a first conductive layer. The N+ polysilicon layer has a second surface substantially co-planar with the first surface. Additionally, the device includes a P? polysilicon layer overlying the co-planar surface and a floating gate on the P? polysilicon layer. The floating gate is a low-pressure CVD-deposited silicon layer sandwiched by a bottom oxide tunnel layer and an upper oxide block layer. Moreover, the device includes at least one control gate made of a P+ polysilicon layer overlying the upper oxide block layer.

Abstract: A three-dimensional nonvolatile memory array includes a select layer that selectively connects vertical bit lines to horizontal bit lines. Individual select switches of the select layer include two separately controllable transistors that are connected in series between a horizontal bit line and a vertical bit line. Each transistor in a select switch is connected to a different control circuit by a different select line.

Abstract: A nonvolatile memory device includes a substrate; a channel layer projecting from a surface of the substrate, in a direction perpendicular to the surface; a tunnel dielectric layer surrounding the channel layer; a plurality of interlayer dielectric layers and a plurality of control gate electrodes alternately formed along the channel layer; floating gate electrodes interposed between the tunnel dielectric layer and the plurality of control gate electrodes, the floating gate electrodes comprising a metal-semiconductor compound; and a charge blocking layer interposed between each of the plurality of control gate electrodes and each of the plurality of floating gate electrodes.

Abstract: A nonvolatile memory device includes a substrate having active regions that are defined by an isolation layer and that have first sidewalls extending upward from the isolation layer, floating gates adjoining the first sidewalls of the active regions with a tunnel dielectric layer interposed between the active regions and the floating gates and extending upward from the substrate, an intergate dielectric layer disposed over the floating gates, and control gates disposed over the intergate dielectric layer.

Abstract: A semiconductor device includes a substrate, a plurality of insulating layers vertically stacked on the substrate, a plurality of channels arranged in vertical openings formed through at least some of the plurality of insulating layers, and a plurality of portions alternatingly positioned with the plurality of insulating layers in the vertical direction. At least some of the portions are adjacent corresponding channels of the plurality of channels. Each of the portions includes a conductive barrier pattern formed on an inner wall of the portion, a filling layer pattern positioned in the portion on the conductive barrier pattern, and a gate electrode positioned in a remaining area of the portion not occupied by the conductive barrier or filling layer pattern.

Abstract: A three-dimensional semiconductor device and a method of fabricating the same, the device including a lower insulating layer on a top surface of a substrate; an electrode structure sequentially stacked on the lower insulating layer, the electrode structure including conductive patterns; a semiconductor pattern penetrating the electrode structure and the lower insulating layer and being connected to the substrate; and a vertical insulating layer interposed between the semiconductor pattern and the electrode structure, the vertical insulating layer crossing the conductive patterns in a vertical direction and being in contact with a top surface of the lower insulating layer.

Abstract: Provided are a semiconductor device and a method of manufacturing the same. The semiconductor device includes: a memory array on a first substrate; and a peripheral circuit on a second substrate, wherein the first substrate and the second substrate may be attached to each other so that the memory array and the peripheral circuit are electrically connected to each other.

Abstract: A NAND device has at least a 3×3 array of vertical NAND strings in which the control gate electrodes are continuous in the array and do not have an air gap or a dielectric filled trench in the array. The NAND device is formed by first forming a lower select gate level having separated lower select gates, then forming plural memory device levels containing a plurality of NAND string portions, and then forming an upper select gate level over the memory device levels having separated upper select gates.

Abstract: An object is to suppress reading error even in the case where writing and erasing are repeatedly performed. Further, another object is to reduce writing voltage and erasing voltage while increase in the area of a memory transistor is suppressed. A floating gate and a control gate are provided with an insulating film interposed therebetween over a first semiconductor layer for writing operation and erasing operation and a second semiconductor layer for reading operation which are provided over a substrate; injection and release of electrons to and from the floating gate are performed using the first semiconductor layer; and reading is performed using the second semiconductor layer.

Abstract: The technology of the present invention relates to a non-volatile memory device and a fabrication method thereof. The non-volatile memory device includes channel layers protruding vertically from a substrate, a plurality of hole-supply layers and a plurality of gate electrodes, which are alternately stacked along the channel layers, and a memory film interposed between the channel layers and the gate electrodes and between the hole-supply layers and the gate electrodes. According to this technology, the hole-supply layers are formed between the memory cells such that sufficient holes are supplied to the memory cells during the erase operation of the memory cells, whereby the erase operation of the memory cells is smoothly performed without using the GIDL current, and the properties of the device are protected from being deteriorated due to program/erase cycling.