This application is based upon and claims the benefit of priority from Japanese Patent Application No. 2006-203325, filed on Jul. 26, 2006, the entire contents of which are incorporated herein by reference.
1. Technical Field
The present invention relates to a nonvolatile semiconductor memory device, such as a NAND nonvolatile semiconductor memory device, capable of being manufactured by a simplified process and having an increased storage capacity.
2. Description of Related Art
NAND nonvolatile semiconductor memory devices includes a series connected plural transistors as memory cells each including a charge storage layer in a gate insulating film and select gate transistors (generally, MOS transistors) respectively connected to the two ends of the series connection. As an example of the transistor used for the memory sell, there is used the following transistors: a memory cell transistor having a layered gate structure including a floating gate electrode layer; or a memory cell transistor having MONOS structure or SONOS structure, which includes an insulating film (ONO structure) as a gate insulating film having a silicon oxide film/silicon nitride film/silicon oxide film layered structure.
When the select gate transistor has the same layered structure as the memory cell transistor, electrons or holes may be stored in the charge storage layer of the select gate transistor due to, for example, voltage stress at the time of read state although it is not intended to perform write or erase operations on the select gate transistor as a target. In this case, when the select gate transistor is n-channel MOS transistor, the select gate transistor is not turned on because of increase of the threshold voltage or is not turned off because of decrease of the threshold voltage, which results in that the selectivity is impaired. For this reason, the select gate transistor needs to be formed by a different manufacturing process than the memory cell transistors.
In case where the memory cell transistor has the ONO structure, after a silicon oxide film, a silicon nitride film, and a silicon oxide film are formed on a silicon semiconductor substrate, or after a silicon oxide film and a silicon nitride film are formed on a silicon semiconductor substrate, the formed insulating films are removed in a region for forming a select gate transistor, a silicon oxide film is then formed at the region by oxidation, and a select gate transistor is finally formed as a usual MOS transistor.
In case where the memory cell transistor has the floating gate structure, it is desirable that the select gate transistor and the memory cell transistor have the same structure in a gate processing including lithography. Therefore, although the gate electrode of the lower layer is not separated for each select gate transistor, the select gate transistor also becomes a two-layer structure. However, it becomes a floating gate structure as it is and thus it is necessary to provide a contact portion of a two-layer gate including a floating gate electrode layer and a control gate electrode layer at a cell array end or in a cell array.
As described above, the presence of the select gate transistor complicates the manufacturing process. Furthermore, spaces for forming separated gate insulating films or regions for short-circuiting the two-layer gate electrodes are needed between the select gate transistors and the memory cell transistors, which result in increase in the memory cell size or the memory cell array area.
JP-A-5-326892 (see FIG. 4 of this document) discloses a NAND nonvolatile semiconductor memory device in which a diode, instead of the source-side select gate transistor, is connected in series to the memory cell transistors. Write operation is prohibited by charging-up of the channel region by utilizing the characteristics of the diode to turn off when a reverse voltage is applied. At the time of read operation, the diode is turned on by applying voltage to the source line side and voltage is applied to the gate electrodes of the memory cell transistors which are connected to the diode in series. A “1” or “0” state of the memory cell transistor of a target memory cell can be read out depending on whether it is on or off.
US 2004/0124466 A1 and A. J. Walker et al. (“3D TFT-SONOS Memory Cell for Ultra-High Density File Storage Applications,” 2003 Symposium on VLSI Technology Digest of Technical Papers, June 2003) discloses an example in which memory cell transistors, which are thin-film transistors (TFTs) having an ONO structure charge storage dielectric layer are connected to each other in series to form a NAND string, are applied to a 3D flash memory. Likewise, US 2004/0155302 A1 discloses a 3D mask programmable ROM and its peripheral circuit configuration.
Although the storage capacity of memories has been increased by the miniaturization, investments are increasing as the degree of miniaturization increases. As a result, a tendency to produce an inexpensive, high-capacity layered memory using facilities which are low in running cost though the process is long is now increasing (see the document by A. J. Walker et al referred above).
M. Johnson et al. (“512-Mb PROM with a Three-Dimensional Array of Diode/Antifuse Memory Cells,” IEEE J. Solid-State Circuits, Vol. 38, No. 11, pp. 1,920-1,928, November 2003) discloses a 3D PROM including diode/antifuse memory cells having a stacked structure in which eight layers are stacked in the vertical direction. Furthermore, K-D. Sung et al. (“A 3.3-V, 32 Mb NAND Flash Memory with Incremental Step Pulse Programming Scheme,” 1995 IEEE International Solid-State Circuits Conference, pp. 128-129, Feb. 15-17, 1995) discloses an incremental step pulse programming (ISPP) NAND flash memory capable of reducing the page program current by self-boosting the program suppression voltage and capable of attaining high-speed read throughput by interleaved data paths.
According to a first aspect of the invention, there is provided a nonvolatile semiconductor memory device including: a source-line-side diode an anode region that is connected to a source line; a bit-line-side diode a cathode region that is connected to a bit line; and memory cell string connected between a cathode region of the source-line-side diode and an anode region of the bit-line-side diode, the memory cell string including a series connection of a plurality of memory cell transistors containing a first stage transistor connected to the source-line-side diode and a last stage transistor connected to the bit-line-side diode, wherein the source-line-side diode is formed in a contact for connecting the source line and the memory cell string in a first direction perpendicular to a semiconductor substrate, and the bit-line-side diode is formed in a contact for connecting the bit line and the memory cell string in the first direction.
According to a second aspect of the invention, there is provided a nonvolatile semiconductor memory device including: a first source-line-side diode having an anode region connected to a source line; a first bit-line-side diode having a cathode region connected to a first bit line; a first memory cell string connected between a cathode region of the first source-line-side diode and an anode region of the first bit-line-side diode, the first memory cell string including a series connection of a plurality of memory cell transistors; a second source-line-side diode having an anode region connected to the source line; a second bit-line-side diode having a cathode region connected to a second bit line; and a second memory cell string connected between a cathode region of the second source-line-side diode and an anode region of the second bit-line-side diode, the second memory cell string including a series connection of a plurality of memory cell transistors, wherein the first memory cell string and the second memory cell string are layered above a semiconductor substrate via an interlayer insulating film, wherein each of the first and second source-line-side diodes is formed in a contact for connecting the source line and the first or second memory cell string in a first direction perpendicular to the semiconductor substrate, wherein the first bit-line-side diode is formed in a contact for connecting the first bit line and the first memory cell string in the first direction, and wherein the second bit-line-side diode is formed in a contact for connecting the second bit line and the second memory cell string in the first direction.
According to a third aspect of the invention, there is provided a nonvolatile semiconductor memory device including; a first source-line-side diode having an anode region connected to a first source line; a bit-line-side diode having a cathode region connected to a bit line; a first memory cell string connected between a cathode region of the first source-line-side diode and an anode region of the bit-line-side diode, the first memory cell string including a series connection of a plurality of memory cell transistors; a second source-line-side diode having an anode region connected to a second source line; and a second memory cell string connected between a cathode region of the second source-line-side diode and the anode region of the bit-line-side diode, the second memory cell string including a series connection of a plurality of memory cell transistors, wherein the first memory cell string and the second memory cell string are formed in a same layer above a semiconductor substrate via an interlayer insulating film, wherein the first source-line-side diode is formed in a contact for connecting the first source line and the first memory cell string in a first direction perpendicular to the semiconductor substrate, wherein the second source-line-side diode is formed in a contact for connecting the second source line and the second memory cell string in the first direction, and wherein the bit-line-side diode is formed in a contact for connecting the bit line and the first and second memory cell strings in the first direction.
FIG. 1 shows a schematic circuit configuration of a NAND cell unit of a nonvolatile semiconductor memory device according to a first embodiment of the present invention in which diodes are employed as select gates and the memory cell transistor has a stack gate structure;
FIG. 2 shows a schematic circuit configuration of a NAND cell unit of a nonvolatile semiconductor memory device according to the first embodiment of the invention in which diodes are employed as select gates and the memory cell transistor has a SONOS structure;
FIG. 3 shows a schematic entire block configuration of the nonvolatile semiconductor memory device according to the first embodiment of the invention;
FIG. 4 shows a detailed entire block configuration of the nonvolatile semiconductor memory device according to the first embodiment of the invention;
FIGS. 5A and 5B show a schematic circuit configuration and a schematic sectional structure, taken along the bit line extending direction (line I-I), of NAND cell units of the nonvolatile semiconductor memory device according to the first embodiment of the invention in which diodes are employed as the select gates and the memory cell transistor has the stack gate structure;
FIG. 6 shows an example of operation voltage of the nonvolatile semiconductor memory device according to the first embodiment of the invention.
FIGS. 7A and 7B show a schematic circuit configuration and a schematic sectional structure, taken along the bit line extending direction (line I-I), of NAND cell units of a nonvolatile semiconductor memory device according to a second embodiment of the invention in which diodes are employed as the select gates and the memory cell transistor has the stack gate structure;
FIG. 8 shows an example of operation voltage of the nonvolatile semiconductor memory device according to the second embodiment of the invention.
FIG. 9 shows operation waveforms in an erase operation, which conform to the operation voltage shown in FIG. 8 , of the nonvolatile semiconductor memory device according to the second embodiment of the invention;
FIG. 10 shows operation waveforms in a write operation, which conform to the operation voltage shown in FIG. 8, of the nonvolatile semiconductor memory device according to the second embodiment of the invention;
FIG. 11 shows operation waveforms in a read operation, which conform to the operation voltage shown in FIG. 8, of the nonvolatile semiconductor memory device according to the second embodiment of the invention;
FIG. 12 shows a circuit configuration of layered NAND cell units (four layers) of a nonvolatile semiconductor memory device according to a third embodiment of the invention in which diodes are employed as select gates and the memory cell transistor has the stack gate structure;
FIG. 13 shows a circuit configuration of layered NAND cell units (four layers) of a nonvolatile semiconductor memory device according to the third embodiment of the invention in which diodes are employed as select gates and the memory cell transistor has the SONOS structure;
FIGS. 14A and 14B show a schematic circuit configuration and a schematic sectional structure, taken along the bit line extending direction (line I-I), of one layer of layered NAND cell units of the nonvolatile semiconductor memory device according to the third embodiment of the invention in which diodes are employed as the select gates and the memory cell transistor has a SONOS/TFT structure;
FIG. 15 shows an example of operation voltage of the nonvolatile semiconductor memory device according to the third embodiment of the invention;
FIG. 16 shows a schematic circuit configuration of layered NAND cell units (four layers) of a nonvolatile semiconductor memory device according to the third embodiment of the invention in which diodes are employed as the select gates and the memory cell transistor has the SONOS/TFT structure;
FIG. 17 shows a schematic sectional structure, taken along the bit line extending direction (line I-I), of the layered NAND cell units (four layers) of the nonvolatile semiconductor memory device according to the third embodiment of the invention in which diodes are employed as the select gates and the memory cell transistor has the SONOS/TFT structure;
FIG. 18 shows a schematic sectional structure, taken along the bit line extending direction (line I-I), of layered NAND cell units (four layers) of a nonvolatile semiconductor memory device according to a modification of the third embodiment of the invention in which the positional relationship between the bit line BL and the source line STL is opposite to that of the structure shown in FIG. 17;
FIG. 19 shows a schematic circuit configuration of a NAND cell unit array of the nonvolatile semiconductor memory device according to the third embodiment in which diodes are employed as the select gates and the memory cell transistor has the SONOS/TFT structure;
FIG. 20 shows a schematic circuit configuration of layered NAND cell units (four layers) of a nonvolatile semiconductor memory device according to a fourth embodiment of the invention in which diodes are employed as the select gates and the memory cell transistor has the SONOS/TFT structure;
FIG. 21 shows a schematic sectional structure, taken along the bit line extending direction (line I-I), of the layered NAND cell units (four layers) of the nonvolatile semiconductor memory device according to the fourth embodiment of the invention in which diodes are employed as the select gates, the memory cell transistor has the SONOS/TFT structure, and a source line STL or a bit line BL is shared by vertically adjoining NAND cell units;
FIGS. 22A to 22D are schematic planar pattern diagrams for description of wiring at end portions of a memory cell array of layered NAND cell units (four layers) of the nonvolatile semiconductor memory device according to the fourth embodiment of the invention in which diodes are employed as the select gates and the memory cell transistor has the SONOS/TFT structure, in which FIG. 22A is a schematic diagram showing contacts which connect the first layer of the memory cell array to a CMOS layer, FIG. 22B is a schematic diagram showing contacts which connect the second layer of the memory cell array to its first layer, FIG. 22C is a schematic diagram showing contacts which connect the third layer of the memory cell array to its second layer, and FIG. 22D is a schematic diagram showing contacts which connect the fourth layer of the memory cell array to its third layer;
FIG. 23 shows an exemplary planar pattern for reducing the chip size by utilizing free areas produced on the semiconductor substrate surface by layering of a memory cell array in the nonvolatile semiconductor memory device according to the fourth embodiment of the invention.
FIGS. 24A and 24B show a schematic circuit configuration and a schematic sectional structure, taken along the bit line extending direction (line I-I), of NAND cell units of a nonvolatile semiconductor memory device according to a fifth embodiment of the invention in which diodes are employed as the select gates and the memory cell transistor has the stack gate structure;
FIG. 25 shows an example of operation voltage of the nonvolatile semiconductor memory device according to the fifth embodiment of the invention;
FIG. 26 shows operation waveforms in an erase operation, which conform to the operation voltage shown in FIG. 25, of the nonvolatile semiconductor memory device according to the fifth embodiment of the invention;
FIG. 27 shows operation waveforms in a write operation, which conform to the operation voltage shown in FIG. 25, of the nonvolatile semiconductor memory device according to the fifth embodiment of the invention;
FIG. 28 shows operation waveforms in a read operation, which conform to the operation voltage shown in FIG. 25, of the nonvolatile semiconductor memory device according to the fifth embodiment of the invention;
FIG. 29 shows a schematic perspective view of a NAND cell units of a nonvolatile semiconductor memory device according to a sixth embodiment of the invention; and
FIG. 30 shows a schematic sectional structure, taken along the bit line extending direction (line XXX-XXX), of NAND cell units of the nonvolatile semiconductor memory device according to the sixth embodiment of the invention.
First to sixth embodiments of the present invention will be described with reference to the drawings. In the drawings, the same or similar elements are denoted by the same or similar symbols. However, it should be noted that the drawings are schematic and a relationship between a thickness and planar dimensions, a ratio between thicknesses of respective layers, etc. are different from a actual relationship, ratio, etc. Specific thicknesses and dimensions should be judged taking the following description into consideration. It goes without saying that a relationship or a ratio between dimensions may be different in two or more drawings.
The first to sixth embodiments described below are just examples of devices or methods for implementing the technical concept of the invention, and in the technical concept of the invention the materials, shapes, structures, arrangements, etc. of components are not limited to the ones described below. As for the technical concept of the invention, various modifications to the embodiments are possible without departing from the scope of the claims.
(Stack Gate Structure)
An exemplary memory cell transistor employed in a nonvolatile semiconductor memory device according to the first embodiment of the invention has a stack gate structure which includes source/drain regions, a channel region between the source/drain regions, a gate insulating film formed on the channel region, a floating gate electrode formed on the gate insulating film, an intergate insulating film formed on the floating gate electrode, and a control gate electrode formed on the intergate insulating film.
FIG. 1 shows a schematic circuit configuration of a NAND cell unit 35 of the nonvolatile semiconductor memory device according to the first embodiment of the invention in which the memory cell transistor has the stack gate structure. The NAND cell unit 35 includes a source-line-side diode DS having an anode region connected to a source line STL, a bit-line-side diode DB having a cathode region connected to a bit line BL, and a memory cell string connected between the cathode region of the source-line-side diode DS and the anode region of the bit-line-side diode DES. The memory cell string includes plural memory cell transistors M 10 , M 11 , M 12 , and M 13 each having the stack gate structure and connected in series via their source/drain regions.
(SONOS Structure)
Another exemplary memory cell transistor employed in a nonvolatile semiconductor memory device according to the first embodiment of the invention has a SONOS structure which includes source/drain regions, a channel region between the source/drain regions, an ONO insulating film formed on the channel region, and a control gate electrode formed on the ONO insulating film.
FIG. 2 shows a schematic circuit configuration of a NAND cell unit 35 of the nonvolatile semiconductor memory device according to the first embodiment of the invention in which the memory cell transistor has the SONOS structure. The NAND cell unit 35 includes a source-line-side diode DS having an anode region connected to a source line STL, a bit-line-side diode DB having a cathode region connected to a bit line BL, and a memory cell string are connected between the cathode region of the source-line-side diode DS and the anode region of the bit-line-side diode DB. The memory cell string includes plural memory cell transistors M 10 , M 11 , M 12 , and M 13 each having the SONOS structure and connected in series via their source/drain regions.
(Entire Block Configuration)
FIG. 3 shows a schematic entire block configuration of the nonvolatile semiconductor memory device according to the first embodiment of the invention. A semiconductor chip 1 includes a memory cell array 2 , a row address decoder 3 disposed around the memory cell 2 , a column address decoder 4 disposed around the memory cell 2 , a status register 5 , an input/output circuit 6 , an SGD/SGS/CG switch 116 , a sense amplifier 120 , a data register 118 , a control circuit 110 , a high-voltage generation circuit 114 , a ready/busy output circuit 112 , an address register 104 , a command register 106 , and an operation logic control circuit 108 .
FIG. 4 shows a detailed entire block configuration of the nonvolatile semiconductor memory device according to the first embodiment of the invention. The sense amplifier 120 , the data register 118 , and the column address decoder 4 are disposed close to the memory cell array 2 in the column direction. The SGD/SGS/CG switch 116 and the row address decoder 3 are disposed close to the memory cell array 2 in the row direction. The high-voltage generation circuit 114 supplies high-voltage signal pulses to the SGD/SGS/CG switch 116 , the memory cell array 2 , and the sense amplifier 120 . The control circuit 110 supplies control signals to the high-voltage generation circuit 114 and the peripheral circuits of the memory cell array 2 . The command register 106 supplies command signals to the control circuit 110 . The address register 104 supplies address signals to the column address decoder 4 and the row address decoder 3 . The status register 5 and the ready/busy output circuit 112 receive control signals from the control circuit 110 . The operation logic control circuit 108 supplies control signals to the control circuit 110 . The input/output circuit 6 receives control signals from the operation logic control circuit 108 , receives status information from the status register 5 , supplies command signals to the command register 106 , and exchanges data with the address register 104 and the data register 118 .
As shown in FIG. 4, input/output ports I/O 1 to I/O 8 for address, data and command are connected to the input/output circuit 6 . As shown in FIG. 4, a chip enable signal/CE, a command latch enable signal CLE, an address latch enable signal ALE, a write enable signal/WE, a read enable signal/RE, and a write protect signal/WP are supplied to the operation logic control circuit 108 . Furthermore, as shown in FIG. 4, the ready/busy output circuit 112 outputs a ready/busy output signal RY//BY via a MO$ transistor. Reference symbols VCC and VSS denote an external power supply potential and a ground potential, respectively. The external power supply potential VCC is used as an internal potential VDD as it is or converted into a power supply voltage VDD inside.
(Device Structure)
To save spaces for forming the diode and thereby increase the integration density, it is desirable that each of the source-line-side diode DS and the bit-line-side diode DB be formed in the direction perpendicular to the surface of the semiconductor substrate 10 . The semiconductor substrate 10 may be either a bulk semiconductor or a well diffusion region in a semiconductor substrate.
Although the following description of the nonvolatile semiconductor memory device according to the first embodiment of the invention will be directed to an example in which the memory cell transistor is a TFT having the stack gate structure, memory cell transistors can be layered in a similar manner also in the case where they are TFTs having the SONOS structure.
In the nonvolatile semiconductor memory device according to the first embodiment of the invention, the memory cell unit is simplified by employing diodes instead of select gate transistors.
FIGS. 5A and 5B respectively show a circuit configuration and a schematic sectional structure of 4-NAND-cell units in which diodes are employed as the selective elements instead of MOS transistors and the memory cell transistor has the stack gate structure. It is assumed that the memory cell transistor is an nMOS transistor. It is 1 o apparent that the memory cell transistor may also be a pMOS transistor (the conductive type is reversed). In this case, the potential relationships and the anode/cathode positions of each diode are reversed.
FIGS. 5A and 5B show, as an example, a first layer (the nearest layer to the semiconductor substrate 10 ) of the layers of memory cell transistors in the nonvolatile semiconductor memory device according to the first embodiment of the invention. Although not shown in any drawings, the positional relationship between the source/drain regions 12 and the control gate electrode 15 may be changed.
FIG. 5A shows the schematic circuit configuration of the NAND cell units of the nonvolatile semiconductor memory device according to the first embodiment of the invention in which diodes are employed as the select gates and the memory cell transistor has the stack gate structure. The NAND cell units includes a source-line-side diode DS having an anode region connected to a source line STLi−1, a bit-line-side diode DB having a cathode region connected to a bit line BL, a memory cell string which is connected between the cathode region of the source-line-side diode DS and the anode region of the bit-line-side diode DB and in which plural memory cell transistors M 10 , M 11 , M 12 , and M 13 having the stack gate structure are connected in series via their source/drain regions 12 , a source-line-side diode DS whose anode region is connected to a source line STLi, and a memory cell string which are connected between the cathode region of the source-line-side diode DS and the anode region of the bit-line-side diode DB and in which plural memory cell transistors M 10 , M 11 , M 12 , and M 13 having the stack gate structure are connected in series via their source/drain regions 12 .
As shown in FIG. 5B, the memory cell transistor used in the nonvolatile semiconductor memory device according to the first embodiment of the invention has a stack gate structure including a semiconductor substrate 10 , source/drain regions 12 formed in the semiconductor substrate 10 , a channel region between the source/drain regions 12 , a gate insulating film 11 formed on the channel region, a floating gate electrode 13 formed on the gate insulating film 11 , an intergate insulating film 14 formed on the floating gate electrode 13 , and a control gate electrode 15 formed on the intergate insulating film 14 .
FIG. 5B shows the schematic sectional structure, taken along the bit line extending direction (line I-I), of the NAND) cell units of the nonvolatile semiconductor memory device according to the first embodiment of the invention in which diodes are employed as the select gates and the memory cell transistor has the stack gate structure. The NAND cell units are provided with a semiconductor substrate 10 , field isolation regions (STI) 8 formed in the semiconductor substrate 10 , a DS cathode region 22 of a source-line-side diode DS formed in the semiconductor substrate 10 , a DS anode region 21 formed on the DS cathode region 22 , a first contact plug 26 formed on the DS anode region 21 , a metal electrode layer 27 formed on the first contact plug 26 and connected to a source line STLi−1 which extends in the row direction, a drain region 12 formed in the semiconductor substrate 10 , a second contact plug 26 formed on the drain region 12 , a metal electrode layer 28 formed on the second contact plug 26 , a DB anode region 18 formed on the metal electrode layer 28 , a DB cathode region 19 formed on the DB anode region 18 , a bit line 20 connected to the DB cathode region 19 and extending in the column direction, and a memory cell string connected between the DS cathode region 22 of the source-line-side diode DS and the drain region 12 that is connected to the DB anode region 18 of the bit-line-side diode DB. The memory cell string includes plural memory cell transistors M 10 , M 11 , M 12 , and M 13 having the stack gate structures which are connected in series via their source/drain regions 129 The above regions etc. are disposed between the field isolation regions 8 .
In the nonvolatile semiconductor memory device according to the first embodiment of the invention, as shown in FIGS. 5A and 5B, the bit-line-side diode DB is used in common for the adjacent two memory cell strings in the column direction. That is, as shown in FIGS. 5A and 5B, the two memory cell strings each including the memory cell transistors M 10 , M 11 , M 12 , and M 13 which are arranged in the column direction (i.e., bit line BL extending direction) are arranged symmetrically with respect to the bit-line-side diode DB. As such, the two memory cell strings are connected to the bit line BL via the common bit-line-side diode DB and disposed between the source lines STLi−1 and STLi.
NAND cell units each including the source line STL, the source-line-side diode DS, the memory cell transistors (M 11 , M 11 , M 12 , and M 13 ), the bit-line-side diode DB, and the bit line BL as shown in FIGS. 5A and 5B may be layered via interlayer insulating films 34 in the direction perpendicular to the surface of the semiconductor substrate 10 .
That is, plural memory cell transistors M 20 , M 21 , M 22 , and M 23 are disposed above the plural memory cell transistors M 10 , M 11 , M 12 , and M 13 via an interlayer insulating film 34 , plural memory cell transistors M 30 , M 31 , M 32 , and M 33 are disposed above the memory cell transistors M 20 , M 21 , M 22 , and M 23 via an interlayer insulating film 34 , and plural memory cell transistors M 40 , M 41 , M 42 , and M 43 are disposed above the memory cell transistors M 30 , M 31 , M 32 , and M 33 via an interlayer insulating film 34 .
In the nonvolatile semiconductor memory device according to the first embodiment of the invention, word lines CG 10 , CG 11 , CG 12 , CG 13 , CG 20 , CG 21 , CG 22 , CG 23 , . . . , CG 40 , CG 41 , CG 42 , and CG 43 which are connected to the control gate electrodes 15 of the respective memory cell transistors extend in the row direction which is perpendicular to the bit lines BL.
To form the source-line-side diode DS adjacent to the source line STL that is connected to the metal electrode layer 27 and an n-type silicon layer of the source region of the memory cell transistor M 10 that is closest to the source line STL, the DS anode region 21 of a p-type silicon layer is buried in the contact. That is, the source region of the memory cell transistor M 10 which is closest to the source line STL is formed as the DS cathode region 22 and the DS anode region 21 is buried between the DS cathode region 22 and the contact plug 26 in the vertical direction.
On the bit line BL side, after an ohmic contact to the drain region 12 of the memory cell transistor M 13 which is closest to the bit line BL is formed by the contact plug 26 , the metal electrode layer 28 is formed on the contact plug 26 and the DS anode region 18 of a p-type silicon layer and the DE cathode region 19 of an n-type silicon layer are buried sequentially on the metal electrode layer 28 . The bit-line-side diode DB is thus formed.
As described above, the occupation area of the NAND cell unit can be reduced by forming the source-line-side diode DS and the bit-line-side diode DE in the source-line-side contact and the bit-line-side contact, respectively.
The source-line-side diode DS located on the side of the source line STL may have a Schottky junction instead of a pn junction. Likewise, the bit-line-side diode DE located on the side of the bit line EL need not always be a pn-junction diode. Since the current direction at read may be one direction, the select element can be a diode instead of a MOS transistor. Since the diode is a two-terminal element, selection is made according to the voltage magnitude relationship between the source line STL and the bit line BL.
(Example of Operation Voltage)
FIG. 6 shows an example of operation voltage of NAND cell units of the nonvolatile semiconductor memory device according to the first embodiment of the invention which use the memory cell transistors having the stack gate structure.
For a selected memory cell string, FIG. 6 shows pulse voltage states of the substrate, the bit line BL, the source line STL, a selected word line CG, and an unselected word line CG in respective operation modes of a read mode, a “0”-write mode, a “1”-write mode, and an erase mode. Likewise, for an unselected memory cell string, FIG. 6 shows pulse voltage states of the bit line BL, the source line STL, and the word lines CG in respective operation modes of a read mode, a “0”-write mode, a “1”-write mode, and an erase mode. In FIG. 6, symbol VDD represents a power supply potential, VSS represents a ground potential, VRR represents a read voltage, VPP represents a write voltage, VEE represents an erase voltage, and VMM represents a bootstrap voltage. The read voltage VRR is set higher than Vth(‘0’) (a threshold voltage in a “0”-written state).
A read operation is performed as charging from the source line STL to the bit line BL. The potential of the bit line BL remains the ground potential VSS or changes to a high level “H” in accordance with the threshold value of a selected memory cell transistor. Such a voltage is judged by the sense amplifier S/A.
A write verify operation and an erase verify operation are basically the same as the read operation except for differences in potential relationships (for example, the potential of a selected word line CG is higher than 0 V in the case of the write verify operation, and the potential of all the word lines CG in a selected memory cell string is 0 V in the case of the erase verify operation)
Write operation is performed in the following manner. To attain “1” write (an erased state is maintained) by self-boosting, the regions under the channels of a NAND cell unit is charged from the source line STL. Then, in the case of “0” write, the voltage of the bit line BL is set at 0 V for discharge and the channel potential is set at VBI (a built-in voltage of the BL-side diode, about 0.6V in the case of a silicon pn diode). In the case of “1” write, the bit line BL is given the power supply voltage VMM (high potential) for a pre-charged state is held, a selected word line CG is given the write voltage VPP, and the voltage of an unselected word line CG in a selected NAND string is increased to the bootstrap voltage VMM, whereby the channel potential is thus bootstrapped to a potential at which write is not caused.
The bootstrap voltage VMM is set at such a potential that “0” is not written to an unselected memory cell transistor in a selected NAND string when the channel potential is low, and that the channel potential of a “1”-written memory cell transistor is increased sufficiently and an erased state is thereby held. The precharge voltage for the source line STL may be set at the power supply voltage VDD. However, where the power supply voltage VDD is about 1.8 V, it is desirable that the precharge voltage for the source line STL be set at the bootstrap voltage VMM.
No problem arises as long as the voltage of the bit line BL at the time of “1” write is such as to prevent a fall of a bootstrap potential. However, setting the voltage of the bit line BL at the time of “1” write comparable to the precharge voltage for the source line STL is advantageous in a sense that it dispenses with formation of an extra power circuit, For example, the power supply voltage VDD may be applied to the bit line BL at “1” write, instead of the bootstrap voltage VMM.
In an erase operation, the erase voltage VEE is applied to the semiconductor substrate 10 , a selected word line CG is given the ground potential VSS, and the source line STL is rendered in a floating state. The erase operation will be described below in detail.
First, an erase operation is performed by applying a high potential to the source region of the memory cell transistor M 10 which is closest to the source line STL, from the source line STL via the source-line-side diode DS. Then, the potential of the word line CG of the memory cell transistor M 10 which is closest to the source line STL is increased to VXX, whereby the high potential is transferred to the drain region of the memory cell transistor M 10 . That is, the high potential is applied to the source region of the next memory cell transistor M 11 to effect erasure. Then, the potential of the word line CG of the memory cell transistor M 11 is increased to VXX, whereby the high potential is transferred to the drain region of the memory cell transistor M 11 . That is, the high potential is applied to the source region of the next memory cell transistor M 12 to effect erasure. The above operation is performed repeatedly, whereby the data of the memory cell transistors M 10 , M 11 , M 12 , and M 13 of the selected memory cell string are erased.
The voltage VXX is a voltage that allows transfer of a high potential (VEE-VBI) where VBI is the built-in voltage of the source-line-side diode DS. The voltage VEE is a voltage that allows a low potential to cause development of a sufficiently strong electric field in the semiconductor substrate 10 through capacitive coupling between the control gate electrode and the floating gate electrode.
The NAND nonvolatile semiconductor memory device according to the first embodiment of the invention makes it possible to miniaturize and simplify each memory cell unit by disposing diodes instead of select gate transistors and to increase the storage capacity by layering the memory cell transistors.
(Device Structure)
In a nonvolatile semiconductor memory device according to a second embodiment of the invention, memory cell transistors M 10 , M 11 , . . . , M 13 are formed on a buried insulating film (BOX) 32 . To save the diode formation spaces and thereby increase the integration density, it is desirable that each of the source-line-side diode DS and the bit-line-side diode DB be formed in the direction perpendicular to a surface of a semiconductor layer (an SOI structure in the case where the semiconductor is silicon) above the buried insulating film (BOX) 32 .
Memory cell transistors which are superior in the cutoff characteristic can be realized by forming those using a thin semiconductor layer.
Although the following description of the nonvolatile semiconductor memory device according to the second embodiment of the invention will be directed to an example in which the memory cell transistor is a TFT having the stack gate structure, memory cell transistors can be layered in a similar manner also in the case where they are TFTs having the SONOS structure.
In the nonvolatile semiconductor memory device according to the second embodiment of the invention, the memory cell unit is simplified by employing diodes instead of select gate transistors.
FIG. 7A and 7B show a circuit configuration and a schematic sectional structure of 4-NAND-cell units in which diodes are employed as the select elements instead of MOS transistors and the memory cell transistor has the stack gate structure. It is assumed that the memory cell transistor is an nMOS transistor. It is apparent that the memory cell transistor may also be a pMOS transistor (the conductive type is reversed). In this case, the potential relationships and the anode/cathode positions of each diode are reversed.
FIGS. 7A and 7B show, as an example, a first layer (the nearest layer to the semiconductor substrate 10 ) of the layers of memory cell transistors in the nonvolatile semiconductor memory device according to the second embodiment of the invention. Although not shown in any drawings, the positional relationship between the source/drain regions 12 and the control gate electrode 15 may be changed.
FIG. 7A shows the schematic circuit configuration of the NAND cell units of the nonvolatile semiconductor memory device according to the second embodiment of the invention in which diodes are employed as the select gates and the memory cell transistor has the stack gate structure. The NAND cell units includes a source-line-side diode DS having an anode region connected to a source line STLi−1, a bit-line-side diode DB having a cathode region connected to a bit line BL, a memory cell string connected between the cathode region of the source-line-side diode DS and the anode region of the bit-line-side diode DS and in which plural memory cell transistors M 10 , M 11 , M 12 , and M 13 having the stack gate structure are connected to each other in series via their source/drain regions 12 , a source-line-side diode DS whose anode region is connected to a source line STLi, and a memory cell string which are connected between the cathode region of the source-line-side diode DS and the anode region of the bit-line-side diode DB and in which plural memory cell transistors M 10 , M 11 , M 12 , and M 13 having the stack gate structure are connected to each other in series via their source/drain regions 12 .
As shown in FIG. 7B, the memory cell transistor used in the nonvolatile semiconductor memory device according to the second embodiment of the invention has a stack gate structure including a semiconductor substrate 10 , a buried insulating film 32 formed on the semiconductor substrate 10 , source/drain regions 12 formed on the buried insulating film 32 , a channel region 25 between the source/drain regions 12 , a gate insulating film 11 formed on the channel region 25 , a floating gate electrode 13 formed on the gate insulating film 11 , an intergate insulating film 14 formed on the floating gate electrode 13 , and a control gate electrode 15 formed on the intergate insulating film 14 .
FIG. 7B shows the schematic sectional structure, taken along the bit line extending direction (line I-I), of the NAND cell units of the nonvolatile semiconductor memory device according to the second embodiment of the invention in which diodes are employed as the select gates and the memory cell transistor has the stack gate structure. The NAND cell units are provided with a semiconductor substrate 10 , a buried insulating film 32 formed on the semiconductor substrate 10 , field isolation regions 8 formed on the buried insulating film 32 , a DS cathode region 22 of a source-line-side diode DS formed on the buried insulating film 32 , a DS anode region 21 formed on the DS cathode region 22 , a contact plug 26 formed on the DS anode region 21 , a metal electrode layer 27 formed on the contact plug 26 and connected to a source line STLi−1 which extends in the row direction, a drain region 12 formed on the buried insulating film 32 , a contact plug 26 formed on the drain region 12 , a metal electrode layer 28 formed on the contact plug 26 , a DB anode region 18 formed on the metal electrode layer 28 , a DB cathode region 19 formed on the DB anode region 18 , a bit line 20 connected to the DB cathode region 19 and extending in the column direction, and a memory cell string connected to the DS cathode region 22 of the source-line-side diode DS and the drain region 12 that is connected to the DB anode region. The memory cell string includes plural memory cell transistors M 10 , M 11 , M 12 , and M 13 having the stack gate structure which are connected in series via their source/drain regions 12 . The above regions etc. are disposed between the field isolation regions 8 .
In the nonvolatile semiconductor memory device according to the second embodiment of the invention, as shown in FIGS. 7A and 7B, the bit-line-side diode DB is used in common for the adjacent two memory cell strings in the column direction. That is, as shown in FIGS. 7A and 7B, the two memory cell strings each including the memory cell transistors M 10 , M 11 , M 12 , and M 13 which are arranged in the column direction (i.e., bit line BL extending direction) are arranged symmetrically with respect to the bit-line-side diode DB. As such, the two memory cell strings are connected to the bit line BL via the common bit-line-side diode DB and disposed between the source lines STLi−1 and STLi.
NAND cell units each including the source line STL, the source-line-side diode DS, the memory cell transistors (M 10 , M 11 , M 12 , and M 13 ), the bit-line-side diode DB, and the bit line BL as shown in FIGS. 7A and 7B may be layered via interlayer insulating films 34 in the direction perpendicular to the surface of the semiconductor substrate 10 .
That is, plural memory cell transistors M 20 , M 21 , M 22 , and M 23 are disposed above the plural memory cell transistors M 10 , M 11 , M 12 , and M 13 via an interlayer insulating film 34 , plural memory cell transistors M 30 , M 31 , M 32 , and M 33 are disposed above the memory cell transistors M 20 , M 21 , M 22 , and M 23 via an interlayer insulating film 34 , and plural memory cell transistors M 40 , M 41 , M 42 , and M 43 are disposed above the memory cell transistors M 30 , M 31 , M 32 , and M 33 via an interlayer insulating film 34 .
In the nonvolatile semiconductor memory device according to the second embodiment of the invention, word lines CG 10 , CG 11 , CG 12 , CG 13 , CG 20 , CG 21 , CG 22 , CG 23 , . . . , CG 40 , CG 41 , CG 42 , and CG 43 which are connected to the control gate electrodes 15 of the respective memory cell transistors extend in the row direction which is perpendicular to the bit lines BL.
To form the source-line-side diode DS adjacent to the source line STL that is connected to the metal electrode layer 27 and an n-type silicon layer of the source region of the memory cell transistor M 10 that is closest to the source line STL, the DS anode region 21 of a p-type silicon layer is buried in the contact. That is, the source region of the memory cell transistor M 10 which is closest to the source line STL is formed as the DS cathode region 22 and the DS anode region 21 is buried between the DS cathode region 22 and the contact plug 26 in the vertical direction.
On the bit line BL side, after an ohmic contact to the drain region 12 of the memory cell transistor M 13 which is closest to the bit line BL is formed by the contact plug 26 , the metal electrode layer 28 is formed on the contact plug 26 and the DB anode region 18 of a p-type silicon layer and the DB cathode region 19 of an n-type silicon layer are buried sequentially on the metal electrode layer 28 . The bit-line-side diode DB is thus formed.
As described above, the occupation area of the NAND cell unit can be reduced by forming the source-line-side diode DS and the bit-line-side diode DB in the source-line-STL-side contact and the bit-line-BL-side contact, respectively.
The source-line-side diode DS located on the side of the source line STL may have a Schottky junction instead of a pn junction. Likewise, the bit-line-side diode DB which is located on the side of the bit line BL need not always be a pn-junction diode. Since the current direction at read may be one direction, the select element can be a diode instead of a MOS transistor. Since the diode is a two-terminal element, selection is made according to the voltage magnitude relationship between the source line STL and the bit line BL.
FIG. 7 shows a structure where an SOI substrate is used. In case where the source/drain regions 12 of the memory cell transistors do not reach the buried insulating film (BOX) 32 and a p-type region as a common back gate exists in the SOI substrate, connecting a back gate line BGL to this p-type region makes it possible to perform a batch erase operation as in the nonvolatile semiconductor memory device according to the first embodiment.
In case where the source/drain regions 12 of the memory cell transistors reach the buried insulating film 32 as shown in FIG. 7, particularly in an erase operation mode, it is difficult to supply a back gate potential to the channel regions 25 sandwiched between the source/drain regions 12 by connecting a back gate line BGL to them. In this case, as described later, the potential of the word line CG of the closest memory cell transistor M 10 is increased to VXX and an operation waveform as shown in FIG. 9 is used.
(Example of Operation Voltage)
FIG. 8 shows an example of operation voltage states of NAND cell units of the nonvolatile semiconductor memory device according to the second embodiment of the invention which use the memory cell transistors having the stack gate structure.
For a selected memory cell string, FIG. 8 shows pulse voltage states of the bit line BL, the source line STL, a selected word line CG, and an unselected word line CG in respective operation modes of a read model a “0”-write mode, a “1”-write mode, and an erase mode. Likewise, for an unselected memory cell string, FIG. 8 shows pulse voltage states of the bit line BL, the source line STL, and the word lines CG in respective operation modes of a read mode, a “0”-write mode, a “1”-write mode, and an erase mode. In FIG. 8, symbol VDD represents a power supply potential, VSS represents a ground potential, VRR represents a read voltage, VPP represents a write voltage, VEE represents an erase voltage, and VMM represents a bootstrap voltage. The voltage VRR is set higher than Vth(‘0’) (a threshold voltage in a “0”-written state).
FIG. 9 shows operation waveforms in an erase operation which conform to the voltage shown in FIG. 8. In FIG. 9, symbol VET represents a built-in potential of a pn junction. FIG. 9 shows pulse voltage applied to the source line STL, the word lines CG 20 -CG 23 , the word lines CG 30 -CG 33 , the word lines CG 40 -CG 43 , the bit line EL, the selected word line CG 10 , the selected word line CG 11 , the selected word line CG 12 , and the selected word line CG 13 . As shown in FIG. 9, the potential of the bit line SL is given by |Vth(‘1’)|-VBI. The parameter Vth(‘1’) represents a threshold voltage in a “1”-written state. The potential of the bit line EL has the waveform shown in FIG. 9 because the intermediate waveform depends on original threshold voltage of the respective memory cell transistors.
FIG. 10 shows operation waveforms in a write operation which conform to the voltage shown in FIG. 8. FIG. 10 shows pulse voltage applied to the source line STL, the bit line BL of a “1”-write cell, the bit line BL of a “0”-write cell, an unselected word line CG, and a selected word line CG.
FIG. 11 shows operation waveforms in a read operation which conform to the voltage shown in FIG. 8. FIG. 11 shows pulse voltage applied to the source line STL, the bit line BL of a “1”-written cell, the bit line EL of a “0”-written cell, an unselected word line CG, and a selected word line CG.
A read operation is performed as charging from the source line STL to the bit line EL. The potential of the bit line BL remains the ground potential VSS or changes to a high level “H” in accordance with the threshold value of a selected memory cell transistor. Such a voltage is judged by the sense amplifier S/A.
A write verify operation and an erase verify operation are basically the same as the read operation except for differences in potential relationships (for example, the potential of a selected word line CG is higher than 0 V in the case of the write verify operation and the potential of all the word lines CG in a selected memory cell string is 0 V in the case of the erase verify operation).
Write operation is performed in the following manner. To attain “1” write (an erased state is maintained) by self-boosting, the regions under the channels of a NAND cell unit is charged from the source line STL. Then, in the case of “0” write, the voltage of the bit line BL is set at 0 V for discharge and the channel potential is set at VBI (a built-in voltage of the BL-side diode, about 0.6V in the case of a silicon pn diode). In the case of “1” write, the bit line BL is given the power supply voltage VDD (high potential) for a pre-charged state is held, a selected word line CG is given the write voltage VPP, and the voltage of an unselected word line CG in a selected NAND string is increased to the bootstrap voltage VMM, whereby the channel potential is thus bootstrapped to a potential at which write is not caused.
The bootstrap voltage VMM is set at such a potential that “0” is not written to an unselected memory cell transistor in a selected NAND string when the channel potential is low, and that the channel potential of a “1”-written memory cell transistor is increased sufficiently and an erased state is thereby held. The precharge voltage for the source line STL may be set at the power supply voltage VDD. However, where the power supply voltage VDD is about 1.8 V, it is desirable that the precharge voltage for the source line STL be set at the bootstrap voltage VMM. No problem arises as long as the voltage of the bit line BL at the time of “1” write is such as to prevent a fall of a bootstrap potential. However, setting the voltage of the bit line BL at the time of “1” write comparable to the precharge voltage for the source line STL is advantageous in a sense that it dispenses with formation of an extra power circuit. For example, the bootstrap voltage VMM may be applied to the bit line BL at “1” write, instead of the power supply voltage VDD. An erase operation will be described below in detail.
First, an erase operation is performed by applying a high potential (VEE-VBI (a built-in voltage of the source-line-side diode DS)) to the source region of the memory cell transistor M 10 which is closest to the source line STL, from the source line STL via the source-line-side diode DS. Then, the high potential is transferred to the drain region of the memory cell transistor M 10 . That is, the high potential is applied to the source region of the next memory cell transistor M 11 to effect erasure. Then, the potential of the word line CG of the memory cell transistor M 11 is increased to VXX, whereby the high potential is transferred to the drain region of the memory cell transistor M 11 . That is, the high potential is applied to the source region of the next memory cell transistor M 12 to effect erasure. The above operation is performed repeatedly, whereby the data of the memory cell transistors M 10 , M 11 , M 12 , and M 13 of the selected memory cell string are erased.
The voltage VXX is a voltage that allows transfer of a high potential (VEE-VBI) where VBI is the built-in voltage of the source-line-side diode DS. The voltage VEE is a voltage that allows a low potential to cause development of a sufficiently strong electric field in the semiconductor substrate 10 through capacitive coupling between the control gate electrode and the floating gate electrode.
It is assumed that the memory cell transistor is an nMOS transistor. It is apparent that the memory cell transistor may also be a pMOS transistor (the conductive type is reversed). In this case, the potential relationships and the anode/cathode positions of each diode are reversed.
The NAND nonvolatile semiconductor memory device according to the second embodiment of the invention makes it possible to miniaturize and simplify each memory cell unit by disposing diodes instead of select gate transistors and to improve the cutoff characteristic (i.e., improve the read characteristic) by forming the memory cell transistors using a thin semiconductor layer.
(Stack Gate Structure)
FIG. 12 shows a schematic circuit configuration of layered NAND cell units (four layers) of a nonvolatile semiconductor memory device according to a third embodiment of the invention in which the memory cell transistor has the stack gate structure. The NAND cell units include a first source-line-side diode DS 1 having an anode region connected to a source line STL, a first bit-line-side diode DB 1 having a cathode region connected to a first bit line BL 1 , a first memory cell string which is connected between the cathode region of the first source-line-side diode DS 1 and the anode region of the first bit-line-side diode DB 1 and in which plural memory cell transistors M 10 , M 11 , M 12 , and M 13 having the stack gate structure are connected in series via their source/drain regions, a second source-line-side diode DS 2 having an anode region connected to the source line STL, a second bit-line-side diode DB 2 having a cathode region connected to a second bit line BL 2 , a second memory cell string which is connected between the cathode region of the second source-line-side diode DS 2 and the anode region of the second bit-line-side diode DB 2 and in which plural memory cell transistors M 20 , M 21 , M 22 , and M 23 having the stack gate structure are connected in series via their source/drain regions, a third source-line-side diode DS 3 having an anode region connected to the source line STL, a third bit-line-side diode DB 3 having a cathode region connected to a third bit line BL 3 , a third memory cell string which is connected between the cathode region of the third source-line-side diode DS 3 and the anode region of the third bit-line-side diode DB 3 and in which plural memory cell transistors M 30 , M 31 , M 32 , and M 33 having the stack gate structure are connected in series via their source/drain regions, a fourth source-line-side diode DS 4 having an anode region connected to the source line STL, a fourth bit-line-side diode DB 4 having a cathode region connected to a fourth bit line BL 4 , and a fourth memory cell string which is connected between the cathode region of the fourth source-line-side diode DS 4 and the anode region of the fourth bit-line-side diode DB 3 and in which plural memory cell transistors M 40 , M 41 , M 42 , and M 43 having the stack gate structure are connected in series via their source/drain regions.
(SONOS Structure)
FIG. 13 shows a schematic circuit configuration of layered NAND cell units (four layers) of a nonvolatile semiconductor memory device according to a third embodiment of the invention in which the memory cell transistor has the SONOS structure. The NAND cell units include a first source-line-side diode DS 1 having an anode region connected to a source line STL, a first bit-line-side diode DB 1 having a cathode region connected to a first bit line BL 1 , a first memory cell string which is connected between the cathode region of the first source-line-side diode DS 1 and the anode region of the first bit-line-side diode DB 1 and in which plural memory cell transistors M 10 , M 11 , M 12 , and M 13 having the SONOS structure are connected in series via their source/drain regions, a second source-line-side diode DS 2 having an anode region connected to the source line STL, a second bit-line-side diode DS 2 having a cathode region connected to a second bit line BL 2 , a second memory cell string which is connected between the cathode region of the second source-line-side diode DS 2 and the anode region of the second bit-line-side diode DB 2 and in which plural memory cell transistors M 20 , M 21 , M 22 , and M 23 having the SONOS structure are connected in series via their source/drain regions, a third source-line-side diode DS 3 having an anode region connected to the source line STL, a third bit-line-side diode DB 3 having a cathode region connected to a third bit line BL 3 , a third memory cell string which is connected between the cathode region of the third source-line-side diode DS 3 and the anode region of the third bit-line-side diode DB 3 and in which plural memory cell transistors M 30 , M 31 , M 32 , and M 33 having the SONOS structure are connected in series via their source/drain regions, a fourth source-line-side diode DS 4 having an anode region connected to the source line STL, a fourth bit-line-side diode DB 4 having a cathode region connected to a fourth bit line BL 4 , and a fourth memory cell string which is connected between the cathode region of the fourth source-line-side diode DS 4 and the anode region of the fourth bit-line-side diode DB 3 and in which plural memory cell transistors M 40 , M 41 , M 42 , and M 43 having the SONOS structure are connected in series via their source/drain regions.
In the first to fourth memory cell strings of the nonvolatile semiconductor memory device according to the third embodiment of the invention, control gate electrodes of the respective memory cell transistors are connected to different word lines CG 10 , CG 11 , CG 12 , CG 13 , CG 20 , CG 21 , CG 22 , CG 23 , CG 40 , CG 41 , CG 42 , and CG 43 .
In the nonvolatile semiconductor memory device according to the third embodiment of the invention, the first to fourth memory cell strings are disposed in the four layers which are insulated from each other by interlayer insulating films. Therefore, the sixteen (16) series-connected NAND memory cell transistors can be realized in such a manner as to have the same occupation area as four series-connected NAND memory cell transistors do.
In the nonvolatile semiconductor memory device according to the third embodiment of the invention, the number of series-connected memory cell transistors in each memory cell string is not limited to four. The number of layers is not limited to four either. For example, to realize high-speed read, each memory cell string may be formed by only one memory cell transistor.
In the nonvolatile semiconductor memory device according to the third embodiment of the invention, each of the source-line-side diodes DS 1 -DS 4 is formed in the direction perpendicular to the semiconductor substrate and each of the bit-line-side diodes DB 1 -DB 4 is also done so. For example, each of the source-line-side diodes DS 1 -DS 4 may exist in a contact for connecting the source line STL and the associated memory cell string. For example, each of the bit-line-side diodes DB 1 -DD 4 may exist in a contact for connecting the associated bit line BL and the associated memory cell string.
(Device Structure)
In the nonvolatile semiconductor memory device according to the third embodiment of the invention, the storage capacity is increased by layering the memory cell transistors M 10 , M 11 , . . . , M 42 , and M 43 formed in the interlayer insulating films 34 . However, to attain “1” write (an erased state is maintained) by self-boosting, the cutoff characteristics of the source-line-side diode DS and the bit-line-side diode BD are important. Furthermore, to save the diode formation spaces and thereby increase the integration density, it is desirable that each of the source-line-side diode DS and the bit-line-side diode BD be formed in the vertical direction.
The memory cell transistors M 10 , M 11 , . . . , M 42 , and M 43 which are layered so as to be formed in the interlayer insulating films 34 are TFTs. Source/drain regions 12 and channel regions 25 of the memory cell transistors M 10 , M 11 , . . . , M 42 , and M 43 can be formed by re-crystallizing deposited amorphous silicon or polysilicon by a laser annealing technique or the like. Alternatively, Source/drain regions 12 and channel regions 25 of the memory cell transistors M 10 , M 11 , M 42 , and M 43 can be formed by using deposited amorphous silicon or polysilicon as it is. This is because satisfactory results are obtained as long as electrons or holes are accumulated at trap levels in the case where the memory cell transistors M 10 , M 11 , . . . , M 42 , and M 43 have the ONO gate structure or in the floating gate electrode layer in the case where they have the floating gate structure and the threshold value is thereby varied.
In case where a single crystal is formed by performing laser annealing or the like on amorphous silicon or polysilicon, a structure shown in FIG. 14B having a SONOS/TFT structure and shallow source/drain regions 12 can be produced more easily.
In case where amorphous silicon or polysilicon is used, nitriding may be performed to suppress generation of dangling bonds. Therefore, an SNONONS structure may be employed. A SANOS structure may also be employed in which an alumna (Al 2 O 3 ) film having large relative permittivity is used instead of the control-gate-side silicon oxide film. Furthermore, a MONOS structure or a MANOS structure using a metal control gate may be employed. Although it is assumed in this embodiment that the TFT as the memory cell transistor is of an n-channel type, it may be of a p-channel type. In the latter case, potential relationships and anode/cathode positions of each of the source-line-side diode DS and the bit-line-side diode DB, which will be described later, are reversed.
Although the following description of the nonvolatile semiconductor memory device according to the third embodiment of the invention will be directed to an example in which the memory cell transistor is a TFT having the SONOS structure, memory cell transistors can be layered in a similar manner also in case of TFTs having the stack gate structure.
In the nonvolatile semiconductor memory device according to the third embodiment of the invention, the memory cell unit is simplified by employing diodes instead of select gate transistors.
FIG. 14A and 14B show a circuit configuration and a schematic sectional structure of 4-NAND-cell units in which diodes are employed as the select elements instead of MOS transistors and the memory cell transistor has the SONOS/TFT structure. It is assumed that the memory cell transistor is an nMOS transistor. It is apparent that the memory cell transistor may also be a pMOS transistor (the conductive type is reversed). In this case, the potential relationships and the anode/cathode positions of each diode are reversed.
FIGS. 14A and 14B show, as an example, a particular layer of the layers of memory cell transistors in the nonvolatile semiconductor memory device according to the third embodiment of the invention. Although not shown in any drawings, the positional relationship between the source/drain regions 12 and the control gate electrode 23 may be changed.
FIG. 14A shows the schematic circuit configuration of the NAND cell units of the nonvolatile semiconductor memory device according to the third embodiment of the invention in which diodes are employed as the select gates and the memory cell transistor has the SONOS/TFT structure. The NAND cell units are provided with a source-line-side diode DS having an anode region connected to a source line STLi−1, a bit-line-side diode DB having a cathode region connected to a bit line BL, a memory cell string which is connected between the cathode region of the source-line-side diode DS and the anode region of the bit-line-side diode DB and in which plural memory cell transistors M 10 , M 11 , M 12 , and M 13 having the SONOS/TFT structure are connected in series via their source/drain regions 12 , a source-line-side diode DS having an anode region connected to a source line STLi, and a memory cell string which is connected between the cathode region of the source-line-side diode DS and the anode region of the bit-line-side diode DB and in which plural memory cell transistors M 10 , M 11 , M 12 , and M 13 having the SONOS/TFT structure are connected to each other in series via their source/drain regions 12 .
As shown in FIG. 14B, the memory cell transistor 1 o used in the nonvolatile semiconductor memory device according to the third embodiment of the invention has a SONOS/TFT structure including an interlayer insulating film 34 , source/drain regions 12 formed in the interlayer insulating film 34 , a channel region 25 between the source/drain regions 12 , an ONO insulating film 24 formed on the channel region 25 , and a control gate electrode 23 formed on the ONO insulating film 24 .
FIG. 14B shows the schematic sectional structure, taken along the bit line extending direction (line I-I), of the NAND cell units of the nonvolatile semiconductor memory device according to the third embodiment of the invention in which diodes are employed as the select gates and the memory cell transistor has the SONOS/TFT structure. The NAND cell units are provided with an interlayer insulating film 34 , field isolation regions 8 formed in the interlayer insulating film 34 , a DS cathode region 22 of a source-line-side diode DS formed in the interlayer insulating film 34 , a DS anode region 21 formed underneath the DS cathode region 22 , a metal electrode layer 27 formed underneath the DS anode region 21 and connected to a source line STLi−1 which extends in the row direction, a drain region 12 formed in the interlayer insulating film 34 , a contact plug 26 formed on the drain region 12 , a DB anode region 18 formed on the contact plug 26 , a DB cathode region 19 formed on the DB anode region 18 , a bit line 20 connected to the DB cathode region 19 and extending in the column direction, and a memory cell string which is connected between the DS cathode region 22 of the source-line-side diode DS and the drain region 12 that is connected to the DB anode region 18 and in which plural memory cell transistors M 10 , M 11 , M 12 , and M 13 having the SONOS/TFT structure are connected in series via their source/drain regions 12 . The above regions etc. are disposed between the field isolation regions 8 .
In the nonvolatile semiconductor memory device according to the third embodiment of the invention, as shown in FIGS. 14A and 14B, the bit-line-side diode DB is used in common for the adjacent two memory cell strings in the column direction. That is, as shown in FIGS. 14A and 14B, the two memory cell strings each including the memory cell transistors M 10 , M 11 , M 12 , and M 13 which are arranged in the column direction (i.e., bit line BL extending direction) are arranged symmetrically with respect to the bit-line-side diode DB. As such, the two memory cell strings are connected to the bit line BL via the common bit-line-side diode DB and disposed between the source lines STLi−1 and STLi.
The NAND cell units each including the source line STL, the source-line-side diode DS, the memory cell transistors (M 10 , M 11 , M 12 , and M 13 ), the bit-line-side diode DB, and the bit line BL as shown in FIGS. 14A and 14B are layered in the vertical direction via the interlayer insulating films 34 .
That is, the plural memory cell transistors M 20 , M 21 , M 22 , and M 23 are disposed above the plural memory cell transistors M 10 , M 11 , M 12 , and M 13 via the interlayer insulating film 34 , the plural memory cell transistors M 30 , M 31 , M 32 , and M 33 are disposed above the memory cell transistors M 20 , M 21 , M 22 , and M 23 via the interlayer insulating film 34 , and the plural memory cell transistors M 40 , M 41 , M 42 , and M 43 are disposed above the memory cell transistors M 30 , M 31 , M 32 , and M 33 via the interlayer insulating film 34 .
In the nonvolatile semiconductor memory device according to the third embodiment of the invention, the word lines CG 10 , CG 11 , CG 12 , CG 13 , CG 20 , CG 21 , CG 22 , CG 23 , . . . , CG 40 , CG 41 , CG 42 , and CG 43 which are connected to the control gate electrodes 23 of the respective memory cell transistors extend in the row direction which is perpendicular to the bit lines BL.
To form the source-line-side diode DS adjacent to the source line STL that is connected to the metal electrode layer 27 and an n-type silicon layer of the source region of the memory cell transistor M 10 that is closest to the source line STL, the DS anode region 21 of a p-type silicon layer is buried in the contact. That is, the source region of the memory cell transistor M 10 which is closest to the source line STL is formed as the DS cathode region 22 and the DS anode region 21 is buried between the DS cathode region 22 and the metal electrode layer 27 in the vertical direction.
On the bit line BL side, after an ohmic contact to the drain region 12 of the memory cell transistor M 13 which is closest to the bit line BL is formed by the contact plug 26 , the DB anode region 18 of a p-type silicon layer and the DB cathode region 19 of an n-type silicon layer are buried sequentially on the contact plug 26 . The bit-line-side diode DB is thus formed.
As described above, the occupation area of the NAND cell unit can be reduced by forming the source-line-side diode DS and the bit-line-side diode DB in the source-line-side contact and the bit-line-side contact, respectively.
The source-line-side diode DS located on the side of the source line STL may have a Schottky junction instead of a pn junction. Likewise, the bit-line-side diode DB which is located on the side of the bit line BL need not always be a pn-junction diode. Since the current direction at read may be one direction, the select element can be a diode instead of a MOS transistor. Since the diode is a two-terminal element, selection is made according to the voltage magnitude relationship between the source line STL and the bit line BL.
(Example of Operation Voltage)
FIG. 15 shows an example of operation voltage states of NAND cell units of the nonvolatile semiconductor memory device according to the third embodiment of the invention which use the memory cell transistors having the SONOS/TFT structure.
For a selected memory cell string, FIG. 15 shows pulse voltage states of the bit line BL, the source line STL, a selected word line CG, and an unselected word line CG in respective operation modes of a read mode, a “0”-write mode, a “1”-write mode, and an erase mode. Likewise, for an unselected memory cell string, FIG. 15 shows pulse voltage states of the bit line BL, the source line STL, and the word lines CG in respective operation modes of a read mode, a “0”-write mode, a “1”-write mode, and an erase mode. In FIG. 15, symbol VDD represents a power supply potential, VSS represents a ground potential, VRR represents a read voltage, VPP represents a write voltage, VEE represents an erase voltage, and VMM represents a bootstrap voltage. The voltage VRR is set higher than Vth(‘0’) (a threshold voltage in a “0”-written state).
Operation waveforms in an erase operation which conform to the voltage shown in FIG. 15 are the same as shown in FIG. 9. FIG. 9 shows pulse voltage applied to the source line STL, the word lines CG 20 -CG 23 , the word lines CG 30 -CG 33 , the word lines CG 40 -CG 43 , the bit line BL, the selected word line CG 10 , the selected word line CG 11 , the selected word line CG 12 , and the selected word line CG 13 . As shown in FIG. 9, the potential of the bit line BL is given by |Vth(‘1’)|-VBI. The parameter Vth(‘1’) represents a threshold voltage in a “1”-written state. The potential of the bit line BL has the waveform shown in FIG. 9 because the intermediate waveform depends on original threshold voltage of the respective memory cell transistors.
Operation waveforms in a write operation which conform to the voltage shown in FIG. 15 are the same as shown in FIG. 10. FIG. 10 shows pulse voltage applied to the source line STL, the bit line BL of a “1”-write cell, the bit line BL of a “0”-write cell, an unselected word line CG, and a selected word line CG.
Operation waveforms in a read operation which conform to the voltage shown in FIG. 15 are the same as shown in FIG. 11. FIG. 11 shows pulse voltage applied to the source line STL, the bit line EL of a “1”-written cell, the bit line BL of a “0”-written cell, an unselected word line CG, and a selected word line CG.
A read operation is performed as charging from the source line STL to the bit line BL. The potential of the bit line BL remains the ground potential VSS or changes to a high level “H” in accordance with the threshold value of a selected memory cell transistor. Such a voltage is judged by the sense amplifier S/A.
A write verify operation and an erase verify operation are basically the same as the read operation except for differences in potential relationships (for example, the potential of a selected word line CG is higher than 0 V in the case of the write verify operation and the potential of all the word lines CG in a selected memory cell string is 0 V in the case of the erase verify operation).
Write operation is performed in the following manner. To attain “1” write (an erased state is maintained) by self-boosting, the regions under the channels of a NAND cell unit is charged from the source line STL. Then, in the case of “0” write, the voltage of the bit line BL is set at 0 V and the channel potential is set at VB 1 (a built-in voltage of the BL-side diode, about 0.6 V in the case of a silicon pn diode). In the case of “1” write, the bit line BL is given the power supply voltage VDD (high potential) for a pre-charged state is held, a selected word line CG is given the write voltage VPP and the voltage of an unselected word line CG in a selected NAND string is increased to the bootstrap voltage VMM, whereby the channel potential is thus bootstrapped to a potential at which write is not caused.
The bootstrap voltage VMM is set at such a potential that “0” is not written to an unselected memory cell transistor in a selected NAND string when the channel potential is low, and that the channel potential of a “1”-written memory cell transistor is increased sufficiently and an erased state is thereby held. The precharge voltage for the source line STL may be set at the power supply voltage VDD. However, where the power supply voltage VDD is about 1.8 V, it is desirable that the precharge voltage for the source line STL be set at the bootstrap voltage VMM. No problem arises as long as the voltage of the bit line BL at the time of “1” write is such as to prevent a fall of a bootstrap potential. However, setting the voltage of the bit line BL at the time of “1” write comparable to the precharge voltage for the source line STL is advantageous in a sense that it dispenses with formation of an extra power circuit. For example, the bootstrap voltage VMM may be applied to the bit line BL at “1” write, instead of the power supply voltage VDD. An erase operation will be described below in detail.
First, an erase operation is performed by applying a high potential (VEE-VBI (a built-in voltage of the source-line-side diode DS)) to the source region of the memory cell transistor M 10 which is closest to the source line STL, from the source line STL via the source-line-side diode DS. Then, the high potential is transferred to the drain region of the memory cell transistor M 10 . That is, the high potential is applied to the source region of the next memory cell transistor M 11 to effect erasure. Then, the potential of the word line CG of the memory cell transistor M 11 is increased to VXX, whereby the high potential is transferred to the drain region of the memory cell transistor M 11 . That is, the high potential is applied to the source region of the next memory cell transistor M 12 to effect erasure. The above operation is performed repeatedly, whereby the data of the memory cell transistors M 10 , M 11 , M 12 , and M 13 of the selected memory cell string are erased.
The voltage VXX is a voltage that allows transfer of a high potential (VEE-VBI) where VBI is the built-in voltage of the source-line-side diode DS. The voltage VEE is a voltage that allows a low potential to cause development of a sufficiently strong electric field in the semiconductor substrate 10 through capacitive coupling between the control gate electrode and the charge trap levels in the ONO insulating film 24 .
FIG. 16 shows a schematic circuit configuration of layered NAND cell units (four layers) of a nonvolatile semiconductor memory device according to the third embodiment of the invention in which diodes are employed as the select gates and the memory cell transistor has the SONOS/TFT structure. The first layer is provided with a source-line-side diode DS 1 having an anode region connected to a source line STLi−1, a bit-line-side diode DB 1 having a cathode region connected to a bit line BL 1 , a memory cell string which is connected between the cathode region of the source-line-side diode DS 1 and the anode region of the bit-line-side diode DB 1 and in which plural memory cell transistors M 10 , M 11 , M 12 , and M 13 having the SONOS/TFT structure are connected in series via their source/drain regions 12 , a source-line-side diode DS 1 having anode region connected to a source line STLi, and a memory cell string which is connected between the cathode region of the source-line-side diode DS 1 and the anode region of the bit-line-side diode DB 1 and in which plural memory cell transistors M 10 , M 11 , M 12 , and M 13 having the SONOS/TFT structure are connected in series via their source/drain regions 12 .
The second layer is provided with a source-line-side diode DS 2 having an anode region connected to the source line STLi−1, a bit-line-side diode DB 2 having a cathode region connected to a bit line BL 2 , a memory cell string which is connected between the cathode region of the source-line-side diode DS 2 and the anode region of the bit-line-side diode DB 2 and in which plural memory cell transistors M 20 , M 21 , M 22 , and M 23 having the SONOS/TFT structure are connected in series via their source/drain regions 12 , a source-line-side diode DS 2 having an anode region connected to the source line STLi, and a memory cell string which is connected between the cathode region of the source-line-side diode DS 2 and the anode region of the bit-line-side diode DB 2 and in which plural memory cell transistors M 20 , M 21 , M 22 , and M 23 having the SONOS/TFT structure are connected in series via their source/drain regions 12 .
The third layer is provided with a source-line-side diode DS 3 having an anode region connected to the source line STLi−1, a bit-line-side diode DB 3 having a cathode region connected to a bit line BL 3 , a memory cell string which is connected between the cathode region of the source-line-side diode DS 3 and the anode region of the bit-line-side diode DB 3 and in which plural memory cell transistors M 30 , M 31 , M 32 , and M 33 having the SONOS/TFT structure are connected in series via their source/drain regions 12 , a source-line-side diode DS 3 having an anode region connected to the source line STLi, and a memory cell string which is connected between the cathode region of the source-line-side diode DS 3 and the anode region of the bit-line-side diode DB 3 and in which plural memory cell transistors M 30 , M 31 , M 32 , and M 33 having the SONOS/TFT structure are connected in series via their source/drain regions 12 .
The fourth layer is provided with a source-line-side diode DS 4 having an anode region connected to the source line STLi−1, a bit-line-side diode DB 4 having a cathode region connected to a bit line BL 4 , a memory cell string which is connected between the cathode region of the source-line-side diode DS 4 and the anode region of the bit-line-side diode DB 4 and in which plural memory cell transistors M 40 , M 41 , M 42 , and M 43 having the SONOS/TFT structure are connected in series via their source/drain regions 12 , a source-line-side diode DS 4 having an anode region connected to the source line STLi, and a memory cell string which is connected between the cathode region of the source-line-side diode DS 4 and the anode region of the bit-line-side diode DB 4 and in which plural memory cell transistors M 40 , M 41 , M 42 , and M 43 having the SONOS/TFT structure are connected in series via their source/drain regions 12 .
FIG. 17 shows a schematic sectional structure, taken along the bit line extending direction (line I-I), of the layered NAND cell units (four layers) of the nonvolatile semiconductor memory device according to the third embodiment of the invention in which diodes are employed as the select gates and the memory cell transistor has the SONOS/TFT structure. In FIG. 17, four layers of the structure shown in FIG. 14B are laid one on another via the interlayer insulating films 34 .
FIG. 18 shows a schematic sectional structure, taken along the bit line extending direction (line I-I), of layered NAND cell units (four layers) of a nonvolatile semiconductor memory device according to a modification of the third embodiment of the invention in which the positional relationship between the bit line BL and the source line STL is opposite to that of the structure shown in FIG. 17.
As shown in the schematic sectional view of FIG. 18 taken along line I-I, one layer of the NAND cell units of the nonvolatile semiconductor memory device according to the modification of the third embodiment of the invention in which the memory transistor cell has the SONOS/TFT structure is provided with an interlayer insulating film 34 , field isolation regions 8 formed in the interlayer insulating film 34 , a DS cathode region 22 of a source-line-side diode DS formed in the interlayer insulating film 34 , a DS anode region 21 formed on the DS cathode region 22 , a metal electrode layer 27 formed on the DS anode region 21 and connected to a source line STLi−1 which extends in the row direction, a drain region 12 formed in the interlayer insulating film 34 , a contact plug 26 formed underneath the drain region 12 , a DB anode region 18 formed underneath the contact plug 26 , a DB cathode region 19 formed underneath the DB anode region 18 , a bit line 20 connected to the DB cathode region 19 and extending in the column direction, and a memory cell string which is connected between the DS cathode region 22 of the source-line-side diode DS and the drain region 12 that is connected to the DB anode region 18 and in which plural memory cell transistors M 10 , M 11 , M 12 , and M 13 having the SONOS/TFT structure are connected in series via their source/drain regions 12 . The above regions etc. are disposed between the field isolation regions 8 .
In the nonvolatile semiconductor memory device according to the modification of the third embodiment of the invention, as shown in FIG. 18, the bit-line-side diode DB is used in common for the adjacent two memory cell strings in the column direction. That is, as shown in FIG. 18, the two memory cell strings each including the memory cell transistors M 10 , M 11 , M 12 , and M 13 which are arranged in the column direction (i.e., bit line BL extending direction) are arranged symmetrically with respect to the bit-line-side diode DB. As such, the two memory cell strings are connected to the bit line BL via the common bit-line-side diode DB.
As shown in FIG. 18, the NAND cell units each including the source line STL, the source-line-side diode DS, the memory cell transistors (M 10 , M 11 , M 12 , and M 13 ), the bit-line-side diode DB, and the bit line BL are layered in the vertical direction via the interlayer insulating films 34 .
That is, the plural memory cell transistors M 20 , M 21 , M 22 , and M 23 are disposed above the plural memory cell transistors M 10 , M 11 , M 12 , and M 13 via the interlayer insulating film 34 , the plural memory cell transistors M 30 , M 31 , M 32 , and M 33 are disposed above the memory cell transistors M 20 , M 21 , M 22 , and M 23 via the interlayer insulating film 34 , and the plural memory cell transistors M 40 , M 41 , M 42 , and M 43 are disposed above the memory cell transistors M 30 , M 31 , M 32 , and M 33 via the interlayer insulating film 34 .
In the nonvolatile semiconductor memory device according to the modification of the third embodiment of the invention, the word lines CG 10 , CG 11 , CG 12 , CG 13 , CG 20 , CG 21 , CG 22 , CG 23 , . . . , CG 40 , CG 41 , CG 42 , and CG 43 which are connected to the control gate electrodes 23 of the respective memory cell transistors extend in the row direction which is perpendicular to the bit lines BL.
To form the source-line-side diode DS adjacent to the source line STL that is connected to the metal electrode layer 27 and an n-type silicon layer of the source region of the memory cell transistor M 10 that is closest to the source line STL, the DS anode region 21 of a p-type silicon layer is buried in the contact. That is, the source region of the memory cell transistor M 10 which is closest to the source line STL is formed as the DS cathode region 22 and the DS anode region 21 is buried between the DS cathode region 22 and the metal electrode layer 27 in the vertical direction.
On the bit line BL side, in the contact portion for connecting the bit line BL and the drain region 12 of the memory cell transistor M 13 which is closest to the bit line BL, the DB cathode region 19 of an n-type silicon layer is formed on the bit line BL, the DB anode region 18 of a p-type silicon layer is then formed on the DB cathode region 19 , and the contact plug 26 is finally formed on the DB anode region 18 . The bit-line-side diode DB is thus formed.
As described above, the occupation area of the NAND cell unit can be reduced by forming the source-line-side diode DS and the bit-line-side diode DB in the source-line-side contact and the bit-line-side contact, respectively.
In the example of FIG. 18, amorphous silicon or polysilicon is used to form the source/drain regions 12 and the channel regions 25 . The memory cell transistor has the SONOS structure. In case where amorphous silicon or polysilicon is used, nitriding may be performed to suppress generation dangling bonds. Therefore, an SNONONS structure may be employed. Although it is assumed in this modification that the SONOS/TFT is of an n-channel type, it may be of a p-channel type.
FIG. 19 shows a schematic circuit configuration of an exemplary NAND cell unit array of the nonvolatile semiconductor memory device according to the third embodiment of the invention in which diodes are employed as the select gates and the memory cell transistor has the SONOS/TFT structure. The NAND cell unit array is provided with bit lines BL 1 , BL 2 , . . . , BLj, BLj+1, . . . which extend in the column direction and source lines . . . , STLi−1, STLi, . . . , STLk+1, STLk+2, . . . which extend in the row direction. NAND cell units 35 are disposed at the crossing points of the bit lines BL 1 , BL 2 , . . . , BLj, BLj+1, . . . extending in the column direction and the source lines . . . , STLi−1, STLi, . . . , STLk+1, STLk+2, . . . extending in the row direction. In the schematic circuit configuration of FIG. 19, adjoining NAND cell units 35 use a common bit-line-side diode DB as shown in FIG. 16.
The NAND nonvolatile semiconductor memory device according to the third embodiment of the invention makes it possible to miniaturize and simplify each memory cell unit by disposing diodes instead of select gate transistors and to increase the storage capacity by layering the memory cell transistors.
FIG. 20 shows a schematic circuit configuration of layered NAND cell units (four layers) of a nonvolatile semiconductor memory device according to a fourth embodiment of the invention in which diodes are employed as the select gates and the memory cell transistor has the SONOS/TFT structure. In the nonvolatile semiconductor memory device according to the fourth embodiment of the invention, when NAND cell units are layered, a source line STL or a bit line EL is shared by vertically adjoining NAND cell units.
FIG. 21 shows a schematic sectional structure, taken along the bit line extending direction (line I-I), of the layered NAND cell units (four layers) of the nonvolatile semiconductor memory device according to the fourth embodiment of the invention in which diodes are employed as the select gates, the memory cell transistor has the SONOS/TFT structure, and a source line STL or a bit line BL is shared by vertically adjoining NAND cell units. In the nonvolatile semiconductor memory device according to the fourth embodiment of the invention, as shown in FIG. 21, the vertical positional relationship between the combination of the channel region 25 and the source/drain region 12 and the control gate electrode 23 is reversed every layer. However, this vertical positional relationship may be kept the same for all the layers.
As shown in FIG. 20 which shows the schematic circuit configuration of the layered NAND cell units (four layers) of the nonvolatile semiconductor memory device according to the fourth embodiment of the invention in which diodes are employed as the select gates and the memory cell transistor has the SONOS/TFT structure, the first layer is provided with a source-line-side diode DS 1 having an anode region connected to a source line STLi−1, a bit-line-side diode DB 1 having a cathode region connected to a bit line BL 1 , a memory cell string which is connected between the cathode region of the source-line-side diode DS 1 and the anode region of the bit-line-side diode DB 1 and in which plural memory cell transistors M 10 , M 11 , M 12 , and M 13 having the SONOS/TFT structure are connected in series via their source/drain regions 12 , a source-line-side diode DS 1 having an anode region is connected to a source line STLi+1, and a memory cell string which is connected between the cathode region of the source-line-side diode DS 1 and the anode region of the bit-line-side diode DB 1 and in which plural memory cell transistors M 10 , M 11 , M 12 , and M 13 having the SONOS/TFT structure are connected in series via their source/drain regions 12 .
The second layer is provided with a source-line-side diode DS 2 having an anode region connected to the source line STLi−1, a bit-line-side diode DB 2 having a cathode region connected to a bit line BL 2 , a memory cell string which is connected between the cathode region of the source-line-side diode DS 2 and the anode region of the bit-line-side diode DB 2 and in which plural memory cell transistors M 20 , M 21 , M 22 , and M 23 having the SONOS/TFT structure are connected in series via their source/drain regions 12 , a source-line-side diode DS 2 having an anode region connected to the source line STLi+1, and a memory cell string which is connected between the cathode region of the source-line-side diode DS 2 and the anode region of the bit-line-side diode DB 2 and in which plural memory cell transistors M 20 , M 21 , M 22 , and M 23 having the SONOS/TFT structure are connected in series via their source/drain regions 12 .
The third layer is provided with a source-line-side diode DS 3 having an anode region connected to a source line STLi, a bit-line-side diode DB 3 having a cathode region connected to the bit line BL 2 , a memory cell string which is connected between the cathode region of the source-line-side diode DS 3 and the anode region of the bit-line-side diode DB 3 and in which plural memory cell transistors M 30 , M 31 , M 32 , and M 33 having the SONOS/TFT structure are connected in series via their source/drain regions 12 , a source-line-side diode DS 3 having an anode region is connected to a source line STLi+2, and a memory cell string which is connected between the cathode region of the source-line-side diode DS 3 and the anode region of the bit-line-side diode DB 3 and in which plural memory cell transistors M 30 , M 31 , M 32 , and M 33 having the SONOS/TFT structure are connected in series via their source/drain regions 12 .
The fourth layer is provided with a source-line-side diode DS 4 having an anode region connected to the source line STLi, a bit-line-side diode DB 4 having a cathode region connected to a bit line BL 3 , a memory cell string which is connected between the cathode region of the source-line-side diode DS 4 and the anode region of the bit-line-side diode DB 4 and in which plural memory cell transistors M 40 , M 41 , M 42 , and M 43 having the SONOS/TFT structure are connected in series via their source/drain regions 12 , a source-line-side diode DS 4 having an anode region connected to the source line STLi+2, and a memory cell string which is connected between the cathode region of the source-line-side diode DS 4 and the anode region of the bit-line-side diode DB 4 and in which plural memory cell transistors M 40 , M 41 , M 42 , and M 43 having the SONOS/TFT structure connected in series via their source/drain regions 12 .
As shown in FIG. 21 showing the s