Patent Publication Number: US-2022238432-A1

Title: Semiconductor device

Description:
CROSS REFERENCE TO RELATED APPLICATIONS 
     This application is based upon and claims the benefit of priority from the prior Japanese Patent Application No. 2021-011087, filed on Jan. 27, 2021, the entire contents of which are incorporated herein by reference. 
     FIELD 
     The embodiments of the present invention relate to a semiconductor device. 
     BACKGROUND 
     Semiconductor devices such as a NAND flash memory have a structure in which a memory cell array is provided above a CMOS (Complementary Metal Oxide Semiconductor) circuit in some cases for the purpose of downscaling. In such cases, source lines for the memory cell array are arranged between the memory cell array and the CMOS circuit. 
     However, there is a risk that film peeling at end portions of memory chips propagates to inner parts of the memory chips through between the source lines and the memory cell array in a dicing process. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1A  is a schematic perspective view illustrating an example of a semiconductor device according to a first embodiment; 
         FIG. 1B  is a schematic plan view illustrating a stacked body; 
         FIGS. 2A and 2B  are schematic sectional views illustrating an example of memory cells in a three-dimensional structure; 
         FIG. 3  is a schematic plan view illustrating an example of the semiconductor device according to the first embodiment; 
         FIG. 4  is a plan view illustrating a configuration example of the conductive layer and the semiconductor part; 
         FIG. 5  is a plan view illustrating a layout example of the conductive layer and the semiconductor part in a wafer manufacturing process; 
         FIG. 6  is an enlarged view illustrating a configuration example in a frame in  FIG. 5 ; 
         FIG. 7  is an enlarged view illustrating a configuration example in a frame in  FIG. 6 ; 
         FIG. 8  is a sectional view along a line  8 - 8  in  FIG. 7 ; 
         FIG. 9A  is a sectional view illustrating a configuration example of a semiconductor device according to a second embodiment; 
         FIG. 9B  is a sectional view illustrating a configuration example of a semiconductor device according to a modification of the second embodiment; 
         FIG. 10A  is a sectional view illustrating a configuration example of a semiconductor device according to a third embodiment; 
         FIG. 10B  is a sectional view illustrating a configuration example of a semiconductor device according to a modification of the third embodiment; 
         FIG. 11  is a sectional view illustrating a configuration example of a semiconductor device according to a fourth embodiment; and 
         FIG. 12  is a sectional view illustrating a configuration example of a semiconductor device according to a fifth embodiment. 
     
    
    
     DETAILED DESCRIPTION 
     Embodiments will now be explained with reference to the accompanying drawings. The present invention is not limited to the embodiments. In the embodiments, “an upper direction” or “a lower direction” refers to a relative direction when a direction perpendicular to a surface of a semiconductor substrate on which semiconductor elements are provided is assumed as “an upper direction”. Therefore, the term “upper direction” or “lower direction” occasionally differs from an upper direction or a lower direction based on a gravitational acceleration direction. In the present specification and the drawings, elements identical to those described in the foregoing drawings are denoted by like reference characters and detailed explanations thereof are omitted as appropriate. 
     A semiconductor device according to the present embodiment comprises a semiconductor substrate. A first insulating layer is provided on the semiconductor substrate. A first conductive film is provided on the first insulating layer. A first stacked structure is provided on the first conductive film and includes a plurality of first electrode films and a plurality of second insulating layers alternately stacked. A semiconductor member extends in the first stacked structure in a staking direction of the first electrode films. A charge accumulating member is provided between one of the first electrode films and the semiconductor member. A conductive member is provided along an outer edge of the first stacked structure around the first stacked structure and electrically connected to the semiconductor substrate. A second stacked structure is provided at least partially around the conductive member and includes the second insulating layers and a plurality of third insulating layers alternately stacked on the first conductive film. The first conductive film comprises a body part arranged below the first stacked structure, a periphery part provided at a periphery of the body part away from the body part, and a slit part provided in the first conductive film between the conductive member and the second stacked structure in the periphery part. 
     First Embodiment 
       FIG. 1A  is a schematic perspective view illustrating an example of a semiconductor device (for example, a semiconductor storage device  100   a ) according to a first embodiment.  FIG. 1B  is a schematic plan view illustrating a stacked body  2  in  FIG. 1A . In the present specification, the stacking direction of the stacked body  2  is a Z direction. One direction intersecting with, for example, being orthogonal to the Z direction is a Y direction. One direction intersecting with, for example, being orthogonal to the Z and Y directions is an X direction.  FIGS. 2A and 2B  are schematic sectional views illustrating an example of memory cells in a three-dimensional structure.  FIG. 3  is a schematic plan view illustrating an example of the semiconductor device according to the first embodiment. 
     As illustrated in  FIGS. 1A to 3 , the semiconductor storage device  100   a  according to the first embodiment is a non-volatile memory having memory cells in a three-dimensional structure. 
     The semiconductor storage device  100   a  includes a base part  1 , the stacked body  2 , deep slits ST (plate-like parts  3 ), shallow slits SHE (plate-like parts  4 ), and a plurality of columnar parts CL. 
     The base part  1  includes a substrate  10 , an interlayer dielectric film  11 , a conductive layer  12 , and a semiconductor part  13 . The interlayer dielectric film  11  being a first insulating layer is provided on the substrate  10 . The conductive layer  12  is provided on the interlayer dielectric film  11 . The semiconductor part  13  is provided on the conductive layer  12 . 
     The substrate  10  is a semiconductor substrate, for example, a silicon substrate. The conductivity type of silicon (Si) is, for example, the p-type. For example, element isolation regions  10   i  are provided on a surface region of the substrate  10 . The element isolation regions  10   i  are, for example, insulating regions including silicon oxide (SiO 2 ) and define active areas AA in the surface region of the substrate  10 . Source and drain regions of transistors Tr are provided in the active areas AA. The transistors Tr constitute a peripheral circuit (a CMOS circuit) of the non-volatile memory. The CMOS circuit is provided below a buried source layer BSL and is provided on the substrate  10 . The interlayer dielectric film  11  includes, for example, silicon oxide and insulates the transistors Tr. Lines  11   a  are provided in the interlayer dielectric film  11 . Some of the lines  11   a  are electrically connected to the transistors Tr. The conductive layer  12  includes conductive metal, for example, tungsten (W). The semiconductor part  13  includes, for example, silicon. The conductivity type of silicon is, for example, the n-type. The semiconductor part  13  may include a plurality of layers and some of the layers may include undoped silicon. Either the conductive layer  12  or the semiconductor part  13  may be omitted. 
     The conductive layer  12  and the semiconductor part  13  function as a common source line for a memory cell array ( 2   m  in  FIG. 1B ). The conductive layer  12  and the semiconductor part  13  are electrically connected as one unit of a first conductive film and is also collectively referred to as “the buried source layer BSL”. 
     The stacked body  2  being a first stacked structure is provided above the semiconductor substrate  10  and is positioned in the Z direction with respect to the conductive layer  12  and the semiconductor part  13  (the buried source layer BSL). The stacked body  2  is configured by alternately stacking a plurality of electrode films  21  and a plurality of insulating layers (second insulating layers)  22  along the Z direction. The electrode films include conductive metal, for example, tungsten. The insulating layers  22  include, for example, silicon oxide. The insulting layers  22  insulate the electrode films  21  from each other. The number of the electrode films  21  and the insulating layers  22  can be any number. The insulating layers  22  may be, for example, air gaps. For example, an insulating film  2   g  is provided between the stacked body  2  and the semiconductor part  13 . The insulating film  2   g  includes, for example, silicon oxide. The insulating film  2   g  may include a high-dielectric body having a higher relative dielectric constant than that of silicon oxide. The high-dielectric body may be, for example, a metal oxide. 
     The electrode films  21  include at least one source-side selection gate SGS, a plurality of word lines WL, and at least one drain-side selection gate SGD. The source-side selection gate SGS is gate electrodes of source-side selection transistors STS. The word lines WL are gate electrodes of memory cells MC. The drain-side selection gate SGD is gate electrodes of drain-side selection transistors STD. The source-side selection gate SGS is provided in a lower region of the stacked body  2 . The drain-side selection gate SGD is provided in an upper region of the stacked body  2 . The lower region indicates a region in the stacked body  2  on a side closer to the base part  1  and the upper region indicates a region in the stacked body  2  on a side far from the base part  1 . The word lines WL are provided between the source-side selection gate SGS and the drain-side selection gate SGD. 
     The thickness in the Z direction of an insulating layer  22  that insulates the source-side selection gate SGS from the word lines WL among the insulating layers  22  can be, for example, larger than the thickness in the Z direction of each insulating layer  22  that insulates a word line WL and a word line WL from each other. A cover dielectric film (not illustrated) may be further provided on a topmost insulating layer  22  that is farthest from the base part  1 . The cover dielectric film includes, for example, silicon oxide. 
     The semiconductor storage device  100   a  includes a plurality of memory cells MC connected in series between each of the source-side selection transistors STS and each of the drain-side selection transistors STD. A structure in which the source-side selection transistor STS, memory cells MC, and the drain-side selection transistor STD are connected in series is called “memory string” or “NAND string”. Each memory string is connected to, for example, a bit line BL via a contact Cb. Bit lines BL are provided above the stacked body  2  and extend in the Y direction. 
     The deep slits ST and the shallow slits SHE are provided in the stacked body  2 . The deep slits ST extend in the X direction and are provided in the stacked body  2  while penetrating through the stacked body  2  from the top end of the stacked body  2  to the base part  1 . The plate-like parts  3  are lines respectively provided in the deep slits ST ( FIG. 1B ). The plate-like parts  3  are made of a conductive film (a second conductive film) that is electrically insulated from the stacked body  2  by an insulating film (not illustrated) provided on inner walls of the deep slits ST and that is embedded in the deep slits ST to be electrically connected to the buried source layer BSL. The plate-like parts  3  are sometimes filled with, for example, an insulating material such as a silicon oxide film. Meanwhile, the shallow slits SHE extend in the X direction and are provided from the top end of the stacked body  2  to the middle of the stacked body  2 . The shallow slits SHE penetrate through the upper region of the stacked body  2  where the drain-side selection gate SGD is provided. For example, the plate-like parts  4  are respectively provided in the shallow slits SHE ( FIG. 1B ). The plate-like parts  4  are, for example, silicon oxide. 
     As illustrated in  FIG. 1B , the stacked body  2  includes staircase parts  2   s  and the memory cell array  2   m . The staircase parts  2   s  are respectively provided at edge portions of the stacked body  2 . The memory cell array  2   m  is sandwiched or enclosed by the staircase parts  2   s . The deep slits ST are provided from the staircase part  2   s  at one end of the stacked body  2  to the staircase part  2   s  at the other end of the stacked body  2  through the memory cell array  2   m . The shallow slits SHE are provided at least in the memory cell array  2   m.    
     As illustrated in  FIG. 3 , the memory cell array  2   m  includes cell regions (Cell) and tap regions (Tap). The staircase parts  2   s  include staircase regions (Staircase). The tap regions are provided, for example, between a cell region and a staircase region. Although not illustrated in  FIG. 3 , the tap regions may be provided between cell regions. The staircase regions are regions where a plurality of lines  37   a  are provided. The tap regions are regions where lines  37   b  and  37   c  are provided. The lines  37   a  to  37   c  extend, for example, in the Z direction. The lines  37   a  are, for example, electrically connected to the electrode films  21 , respectively. The lines  37   b  are, for example, electrically connected to the conductive layer  12 . The lines  37   c  are, for example, electrically connected to the lines  11   a.    
     A portion of the stacked body  2  sandwiched between two plate-like parts  3  illustrated in  FIG. 1B  is called “block (BLOCK)”. The block is, for example, a smallest unit of data erase. The plate-like parts  4  are provided in the blocks, respectively. A portion of the stacked body  2  between one of the plate-like parts  3  and one of the plate-like parts  4  is called “finger”. The drain-side selection gate SGD is divided for each finger. Therefore, one finger in one block can be brought to a selected state by the drain-side selection gate SGD at the time of data write and read. 
     As illustrated in  FIG. 2A , each of the columnar parts CL is provided in a memory hole MH formed in the stacked body  2 . Each of the columnar parts CL penetrates along the Z direction through the stacked body  2  from the top end of the stacked body  2  and is provided in the stacked body  2  and the buried source layer BSL. Each of the columnar parts CL includes a semiconductor body  210 , a memory film  220 , and a core layer  230 . The columnar parts CL each include the core layer  230  provided at the center, the semiconductor body  210  provided around the core layer  230 , and the memory film  220  provided around the semiconductor body  210 . The semiconductor body  210  is electrically connected to the buried source layer BSL. The memory film  220  serving as a charge accumulating member has charge trapping portions between the semiconductor body  210  and the electrode films  21 . A plurality of columnar parts CL each selected from each finger are connected in common to one bit line BL via contacts Cb. The columnar parts CL are provided, for example, in the cell regions (Cell) ( FIG. 3 ). 
     As illustrated in  FIG. 2B , the shape of the memory hole MH in an X-Y plane is, for example, a circle or an ellipse. A block dielectric film  21   a  constituting a portion of the memory film  220  may be provided between the electrode films  21  and the insulating layers  22 . The block dielectric film  21   a  is, for example, a silicon oxide film or a metal oxide film. One example of the metal oxide is aluminum oxide. A barrier film  21   b  may be provided between the electrode films  21  and the insulating layers  22  and between the electrode films  21  and the memory film  220 . For example, titanium nitride is selected as the barrier film  21   b  when the electrode films  21  are tungsten. The block dielectric film  21   a  suppresses back tunnelling of charges from the electrode films  21  toward the memory film  220 . The barrier film  21   b  improves adhesion between the electrode films  21  and the block dielectric film  21   a.    
     The shape of the semiconductor body  210  being a semiconductor member is, for example, a tube having a bottom. The semiconductor body  210  includes, for example, silicon. Silicon is, for example, polycrystalline silicon including crystallized amorphous silicon. The semiconductor body  210  is, for example, undoped silicon. The semiconductor body  210  may be p-type silicon. The semiconductor body  210  functions as a channel of each of the drain-side selection transistor STD, the memory cells MC, and the source-side selection transistor STS. 
     A portion of the memory film  220  other than the block dielectric film  21   a  is provided between the inner wall of the associated memory hole MH and the semiconductor body  210 . The shape of the memory film  220  is, for example, tubular. The memory cells MC have storage regions between the semiconductor body  210  and the electrode films  21  functioning as the word lines WL and are stacked in the Z direction. The memory film  220  includes, for example, a cover dielectric film  221 , a charge trapping film  222 , and a tunnel dielectric film  223 . The semiconductor body  210 , the charge trapping film  222 , and the tunnel dielectric film  223  extend in the Z direction. 
     The cover dielectric film  221  is provided between the insulating layers  22  and the charge trapping film  222 . The cover dielectric film  221  includes, for example, silicon oxide. The cover dielectric film  221  protects the charge trapping film  222  so as not to be etched when sacrificial films (not illustrated) are respectively replaced with the electrode films  21  (a replacing process). The cover dielectric film  221  may be removed from between the electrode films  21  and the memory film  220  in the replacing process. In this case, for example, the block dielectric film  21   a  is provided between the electrode films  21  and the charge trapping film  222  as illustrated in  FIGS. 2A and 2B . The cover dielectric film  221  may be omitted when the replacing process is not used to form the electrode films  21 . 
     The charge trapping film  222  is provided between the block dielectric film  21   a  and the cover dielectric film  221 , and the tunnel dielectric film  223 . The charge trapping film  222  includes, for example, silicon nitride and has a trapping site that traps charges in the film. Portions of the charge trapping film  222  sandwiched between the electrode films  21  functioning as the word lines WL and the semiconductor body  210  respectively constitute the storage regions of the memory cells MC as charge trapping portions. A threshold voltage of each of the memory cells MC changes according to whether there are charges in the associated charge trapping portion or the amount of charges trapped in the charge trapping portion. Each of the memory cells MC accordingly retains information. 
     The tunnel dielectric film  223  is provided between the semiconductor body  210  and the charge trapping film  222 . The tunnel dielectric film  223  includes, for example, silicon oxide, or silicon oxide and silicon nitride. The tunnel dielectric film  223  is a potential barrier between the semiconductor body  210  and the charge trapping film  222 . For example, when electrons are injected from the semiconductor body  210  to a charge trapping portion (a write operation) and when positive holes are injected from the semiconductor body  210  to a charge trapping portion (an erase operation), the electrons and the positive holes pass (tunnel) through the potential barrier of the tunnel dielectric film  223 . 
     The core layer  230  fills an internal space of the tubular semiconductor body  210 . The shape of the core layer  230  is, for example, columnar. The core layer  230  includes, for example, silicon oxide and is insulative. 
     Each of a plurality of columnar parts CLHR in  FIG. 3  is provided in a hole formed in the stacked body  2 . The holes penetrate through the stacked body  2  from the top end of the stacked body  2  along the Z direction to be provided in the stacked body  2  and the semiconductor part  13 . Each of the columnar parts CLHR includes at least an insulator. The insulator is, for example, silicon oxide. Each of the columnar parts CLHR may have a same structure as that of the columnar parts CL. The columnar parts CLHR are provided, for example, in the staircase regions (Staircase) and the tap regions (Tap). The columnar parts CLHR function as support members for holding voids formed in the staircase regions and the tap regions when sacrificial films (not illustrated) are respectively replaced with the electrode films  21  (the replacing process). A plurality of columnar parts CLC 4  are also provided in the tap regions (Tap) of the stacked body  2 . Each of the columnar parts CLC 4  includes the line  37   b  or  37   c . The lines  37   b  are electrically insulated from the stacked body  2  by an insulator  36   b . The lines  37   b  are electrically connected to the buried source line BSL. The lines  37   c  are electrically insulated from the stacked body  2  by an insulator  36   c . The lines  37   c  are electrically connected to any of the lines  11   a . The staircase regions (Staircase) further include the lines  37   a  functioning as contacts for the electrode films  21  in the stacked body  2 , and insulators  36   a  respectively provided around the lines  37   a.    
     The columnar parts CL, that is, the memory holes MH are arranged in a hexagonal close-packed array between two of the deep slits ST adjacent in the Y direction in a planar layout. The shallow slits SHE are provided so as to overlap with some of the columnar parts CL as illustrated in a frame B 4  in  FIG. 3 . No memory cells are formed on the columnar parts CL formed below the shallow slits SHE. 
       FIG. 4  is a plan view illustrating a configuration example of the conductive layer  12  and the semiconductor part  13  (the buried source layer BSL).  FIG. 4  illustrates a plane of the buried source layer BSL corresponding to the whole of one chip of the semiconductor storage device  100   a.    
     The buried source layer BSL being a first conductive film includes a body part  19 , protruding parts  15 , and a periphery part  17 . The body part  19 , the protruding parts  15 , and the periphery part  17  are made of a same material and in a same layer. In the buried source layer BSL, particularly the body part  19  is electrically connected to the semiconductor body  210  illustrated in  FIGS. 2A and 2B  and functions as sources of the memory cell array  2   m.    
     The body part  19  is provided below the electrode films  21  constituting the memory cell array  2   m . That is, the body part  19  is provided immediately above the transistors Tr constituting the CMOS circuit in  FIG. 1A  and immediately below the memory cell array  2   m  in  FIG. 1B . The body part  19  has a substantially rectangular shape as viewed from the stacking direction (the Z direction) of the stacked body  2  as illustrated in  FIG. 4 . In the present specification, the “substantially rectangular shape” includes also shapes similar to a rectangular shape, such as a quadrangular shape having one or more curved sides, as well as the rectangular shape. 
     The periphery part  17  is provided at a periphery of the body part  19  and is away from the body part  19 . The periphery part  17  is provided on dicing lines and an end portion  1   e  thereof is an outer edge of the chip of the semiconductor storage device  100   a . Therefore, the substrate  10  and the like are cut by dicing at the end portion  1   e . A space part  16  is provided between the periphery part  17  and the body part  19 . 
     The protruding parts  15  are provided partially in the space part  16  between the body part  19  and the periphery part  17  and function as connecting parts that partially connect the body part  19  and the periphery part  17  to each other in the manufacturing process. The protruding parts  15  are separated by an insulating member  25  in a completed product as illustrated in  FIG. 4  and extend in the Y direction from the body part  19  toward the periphery part  17  or from the periphery part  17  toward the body part  19 . A width W 15  of each of the protruding parts  15  in the X direction is narrower than a width W 19  of the body part  19 . That is, while the body part  19  and the periphery part  17  are partially connected via the protruding parts  15  to be configured electrically as one unit in the manufacturing process, the body part  19  and the periphery part  17  are separated by the insulating member  25  after completion. Therefore, since not separated in the manufacturing process, the protruding parts  15  are hereinafter also referred to as “connecting parts  15 ”. The number of the protruding parts  15  is not particularly limited to any specific number. The insulating member  25  may be a seal ring that is provided so as to encompass the body part  19 . 
     In a completed product after formation of the buried source layer BSL, portions of the protruding parts (connecting parts)  15  of the buried source layer BSL are removed and the insulating member  25  is embedded therein as illustrated in  FIG. 4 . Accordingly, the body part  19  and the periphery part  17  are electrically isolated from each other by the insulating member  25 . The plate-like parts  3  configured by embedding a conductive film in the deep slits ST are provided in the body part  19  of the buried source layer BSL ( FIG. 1B ) to obtain a configuration that enables a source voltage to be supplied to the buried source layer BSL via the conductive film in the deep slits ST. 
     After formation of the columnar parts CL (the memory holes MH) or the plate-like parts  3  (the deep slits ST), the protruding parts (the connecting parts)  15  are cut due to formation of the insulating member  25 . In the completed product, the protruding parts  15  connected to the body part  19  are protruded in the Y direction from the body part  19  toward the periphery part  17  as illustrated in  FIG. 4 . The protruding parts  15  connected to the periphery part  17  are protruded in the Y direction from the periphery part  17  toward the body part  19 . The protruding parts  15  of the body part  19  and the protruding parts  15  of the periphery part  17  are respectively provided at positions facing each other. Due to cutting of the protruding parts  15 , the capacity of the buried source layer BSL can be reduced and the source voltage can be controlled at a high speed. 
       FIG. 5  is a plan view illustrating a layout example of the conductive layer  12  and the semiconductor part  13  (the buried source layer BSL) in a wafer manufacturing process. In the manufacturing process, the protruding parts (the connecting parts)  15  electrically connect the body part  19  and the periphery part  17  to each other and release charges accumulated in the body part  19  to the substrate  10  and the like via the periphery part  17  at the time of formation of the columnar parts CL (the memory holes MH) or the plate-like parts  3  (the deep slits ST). Accordingly, arcing between the body part  19  and the lines  11   a  and the like positioned thereunder can be suppressed. In  FIG. 5 , semiconductor chips are still connected at dicing lines DL. 
     Slit parts  18  are provided in the periphery part  17  so as to extend along outer edges of the semiconductor chips. The slit parts  18  may be provided entirely at the peripheries of the semiconductor chips or may be partially omitted. Chip body regions Rc surrounded by the periphery part  17  are regions that will become semiconductor chip bodies after dicing. 
       FIG. 6  is an enlarged view illustrating a configuration example in a frame  300  in  FIG. 5 . The periphery part  17  between two chip body regions Rc includes a kerf region Rk and edge seal regions Res. The dicing line DL is a region cut by a laser or a blade in the dicing process. 
     The kerf region Rk includes slit parts  310 . The edge seal regions Res include slit parts  18 . The slit parts  18  and  310  are provided in the periphery part  17  so as to extend along the outer edge of the body part  19 . It is preferable that the slit parts  18  and  310  be provided to correspond to at least a stacked body  2   a  shown in  FIG. 8  at the periphery of the body part  19  to suppress film peeling. However, the slit parts  18  and  310  may be provided entirely at the periphery of the body part  19 . In the first embodiment, inner portions of the slit parts  18  and  310  are filled with an insulating film (for example, a silicon oxide film). 
     The end portion  1   e  of the semiconductor storage device  100   a  illustrated in  FIG. 4  is included in the dicing line DL in  FIG. 6  and is sometimes subjected to damages due to impact at the time of being cut by dicing. For example, the buried source layer BSL in  FIG. 1  has a risk of peeling from the interlayer dielectric film  11  positioned thereunder or peeling from an interlayer dielectric film  24  or the stacked body  2   a  in  FIG. 8  positioned thereon due to impact caused by the dicing. Damages such as the film peeling cause no problem when the damages remain only on the outermost edge of the periphery part  17  in  FIG. 6 . 
     However, if the slit parts  18  and  310  are not provided, there is a risk that such film peeling propagates from the periphery part  17  to the body part  19 . Film peeling at the body part  19  reduces reliability of the semiconductor storage device  100   a.    
     In order to solve this problem, the semiconductor device according to the present embodiment has the slit parts  18  and  310  provided at the periphery part  17  so as to extend at least along one portion of the outer edge of the body part  19 . Accordingly, the film peeling described above stops at the slit parts  310  or the slit parts  18  and propagation of film peeling from the periphery part  17  to the body part  19  can be suppressed. The slit parts  18  and  310  are provided entirely in the thickness direction (the Z direction) of the periphery part  17 . Therefore, both film peeling between the buried source layer BSL and the interlayer dielectric film  11  positioned thereunder and film peeing between the buried source layer BSL and the interlayer dielectric film  24  or the stacked body  2   a  positioned thereon can be suppressed. 
     On the other hand, if the slit parts  18  and  310  electrically disconnect an inside portion of the periphery part  17  and an outside portion thereof from each other, the outside portion of the periphery part  17  cannot be electrically connected to the body part  19  via the protruding parts (the connecting parts)  15  at the time of formation of the memory holes MH and the deep slits ST. In this case, the protruding parts (the connecting parts)  15  cannot release charges accumulated in the body part  19  to the substrate  10  and the like (the ground) via the outside portion of the periphery part  17 . 
     In contrast thereto, according to the present embodiment, the slit parts  18  and  310  are respectively arranged alternately in a staggered manner as viewed from the Z direction or the X direction. Therefore, the inside portion of the periphery part  17  can be electrically connected to the outside portion thereof, and the outside portion of the periphery part  17  can be electrically connected to the body part  19  via the protruding parts (the connecting parts)  15 . 
       FIG. 7  is an enlarged view illustrating a configuration example in a frame  301  in  FIG. 6 . The slit parts  18  include slit parts  18   a  and slit parts  18   b . As viewed from the stacking direction (the Z direction) of the stacked body  2 , the slit parts  18   a  and  18   b  are arranged alternately in a staggered manner. As viewed from the Z direction, the slit parts  18   a  and  18   b  are not connected to each other and are separated from each other. Therefore, a connecting part C 18  is provided between the slit parts  18   a  and the slit parts  18   b . The connecting part C 18  is a portion of the conductive film of the buried source layer BSL that electrically connects the inside portion of the periphery part  17  and the outside portion thereof to each other in the edge seal regions Res. The inside portion of the periphery part  17  is the buried source layer BSL on a side closer to the body part  19  than the slit parts  18   a  and  18   b . The outside portion of the periphery part  17  is the buried source layer BSL on a side closer to the kerf region Rk than the slit parts  18   a  and  18   b . Accordingly, at the time of forming the memory holes MH and the deep slits ST, charges accumulated in the body part  19  flow to the outside portion of the periphery part  17  via the protruding parts (the connecting parts)  15  and the connecting part C 18  to be emitted to the substrate  10  and the like. 
     As viewed from a first direction (the X direction) from the body part  19  toward the periphery part  17 , end portions of the slit parts  18   a  and  18   b  overlap with each other. Therefore, there is no gap between the slit parts  18   a  and the slit parts  18   b  as viewed from the X direction. Accordingly, the slit parts  18   a  and  18   b  can more reliably suppress progression of film peeling. 
     The slit parts  310  include slit parts  310   a  and slit parts  310   b . As viewed from the Z direction, the slit parts  310   a  and  310   b  are arranged alternately in a staggered manner. As viewed from the Z direction, the slit parts  310   a  and the slit parts  310   b  are not connected to each other and are separated from each other. Therefore, a connecting part C 310  is provided between the slit parts  310   a  and the slit parts  310   b . The connecting part C 310  is a portion of the conductive film of the buried source layer BLS that electrically connects the inside portion of the periphery part  17  and the outside portion thereof to each other in the kerf region Rk. Accordingly, at the time of forming the memory holes MH and the deep slits ST, charges accumulated in the body part  19  flow to the outside portion of the periphery part  17  via the protruding parts (the connection parts)  15  and the connecting part C 310  to be emitted to the substrate  10  and the like. The protruding parts (the connecting parts)  15  are cut by formation of the insulating member  25  after the memory choles MH and the deep slits ST are formed. 
     As viewed from the X direction, end portions of the slit parts  310   a  and  310   b  overlap with each other. Therefore, there is no gap between the slit parts  310   a  and the slit parts  310   b  as viewed from the X direction. Accordingly, the slit parts  310   a  and  310   b  can more reliably suppress progression of film peeling. 
     As described above, according to the present embodiment, the slit parts  18  and  310  can suppress film peeling from the end portion  1   e  in  FIG. 4  from propagating from the periphery part  17  to the body part  19  while keeping the electrical connection between the peripheral part  17  and the body part  19 . 
       FIG. 8  is a sectional view along a line  8 - 8  in  FIG. 7 . In  FIG. 8 , the configuration of the edge seal region Res and the kerf region Rk is illustrated in more detail. In the edge seal region Res, a plurality of layers of the lines  11   a  are provided on the surface of the substrate  10  and the layers of the lines  11   a  are isolated from the surrounding region by the interlayer dielectric film  11 . The layers of the lines  11   a  are preferably connected with ring-shaped contact plugs as viewed from the Z direction and are electrically connected to the buried source layer BSL and a seal ring body SLR provided thereon. The substrate  10 , the interlayer dielectric film  11 , the lines  11   a , and the buried source layer BSL constitute the base part  1 . 
     A multi-layer wiring layer  101  is provided on the seal ring body SLR. The multi-layer wiring layer  101  is electrically connected to the seal ring body SLR. The multi-layer wiring layer  101  can be formed to correspond to the bit lines BL and a wiring layer upper than the bit lines BL. 
     The seal ring body SLR being a conductive member cooperates with the layers of the lines  11   a  to function as a seal ring (an edge seal). This seal ring is provided in the thickness direction (the Z direction) of the chip between the substrate  10  and the multi-layer wiring layer  101  and is electrically connected to the substrate  10 . It is preferable that the seal ring body SLR be continuously provided entirely along the outer edge of the stacked body  2  on the body part  19  as well as the layers of the lines  11   a  in a planar layout. A low-resistance metal such as copper is used as the seal ring body SLR and the layers of the lines  11   a . Accordingly, the seal ring including the seal ring body SLR can release charges to the substrate  10  in order to suppress the memory cell array  2   m , the CMOS circuit, and the like in the semiconductor chip from being broken by ESD (Electro-Static Discharge). Further, the seal ring including the seal ring body SLR can suppress hydrogen from entering from the end portion  1   e  to suppress degradation of the semiconductor chip due to the hydrogen after dicing of the semiconductor chip. 
     The slit parts  18   a  and  18   b  are provided in the buried source layer BSL on the side closer to the kerf region Rk than the seal ring body SLR. The slit parts  18   a  and  18   b  are openings provided in the buried source layer BSL between the seal ring body SLR and the stacked body  2   a  and are filled with a material of the interlayer dielectric film  24 . 
     A crack stopper CST is provided between the slit parts  18   a  and the slit parts  18   b . The crack stopper CST is provided in the thickness direction (the Z direction) of the chip between the base part  1  and the multi-layer wiring layer  101 . It is preferable that the crack stopper CST be continuously provided entirely along the outer edge of the stacked body  2  on the body part  19 . A low-resistance metal such as copper is used as the crack stopper CST. The crack stopper CST is provided to stop film peeling from progressing from the end portion  1   e  of the chip toward the kerf region Rk, the edge seal region Res, and the chip body region Rc. The crack stopper CST also has a function to suppress hydrogen from entering from the end portion  1   e . The crack stopper CST may be used to suppress breaking of an inner part of the chip due to ESD. 
     The stacked body (an ONON structure)  2   a  in which insulating layers (silicon oxide films)  22  being second insulating layers and sacrificial films (silicon nitride films)  23  being third insulating layers are stacked is provided in the kerf region Rk as a second stacked structure on the buried source layer BSL. The stacked body  2   a  is provided along the outer edge of the stacked body  2  on the body part  19  at least partially around the seal ring body SLR. That is, the stacked body  2   a  is provided immediately above at least a portion of the periphery part  17  of the buried source layer BSL. For example, the stacked body  2   a  is provided only on a portion of the periphery part  17  facing a certain side of the periphery of the body part  19  in some cases. The stacked body  2   a  is sometimes provided discontinuously in the manner of islands on the periphery part  17 . Alternatively, the stacked body  2   a  may be continuously provided on the periphery part  17  entirely therearound. Portions of the stacked body  2   a  are sometimes missing due to dicing. When the stacked body  2   a  including the insulating layers  22  and the sacrificial films  23  is provided on the buried source layer BSL, film peeling is likely to occur between the stacked body  2   a  and the buried source line BSL or the like as indicated by an arrow A 0  in  FIG. 8 . The stacked body  2   a  may have a stacked structure including the insulating layers  22  and the electrode films  21 , for example, in at least a portion on the side of the edge seal region Res. Also in this case, film peeling is likely to occur between the stacked body  2   a  and the buried source layer BSL or the like. The electrode films (for example, tungsten)  21  are harder to cut by a dicing blade than the sacrificial films (for example, silicon nitride films)  23 . Therefore, if the stacked body  2   a  in the kerf region Rk has a stacked structure (an OWOW structure) in which the insulating layers  22  and the electrode films  21  are alternately stacked particularly on an outer edge side of the chip, the kerf region Rk is hard to cut by a dicing blade. In contrast thereto, according to the present embodiment, the kerf region Rk is easily cut by a dicing blade because the stacked body  2   a  in the kerf region Rk has the ONON structure. 
     When film peeling between the buried source layer BSL and the stacked body  2   a  progresses from the kerf region Rk, the slit parts  310   a  and  310   b  in  FIG. 7  first suppress the film peeling. The slit parts  18   b  in the edge seal region Res subsequently suppress the film peeling. When the film peeling reaches the slit parts  18   b , the film peeling can be guided in a −Z direction along one of interfaces between the interlayer dielectric film  24  in the slit parts  18   b  and the buried source layer BSL as indicated by an arrow A 1  in  FIG. 8 . The film peeling can also be guided to the −Z direction along the other interface between the interlayer dielectric film  24  in the slit parts  18   b  and the buried source layer BSL as indicated by an arrow A 2 . 
     If the film peeling further progresses in a −X direction, the crack stopper CST and the slit parts  18   a  suppress the film peeling. When the film peeling reaches the slit parts  18   a , the film peeling is guided in the −Z direction along one of interfaces between the interlayer dielectric film  24  in the slit parts  18   a  and the buried source layer BSL as indicated by an arrow A 3 . The film peeling can be guided to the −Z direction along the other interface between the interlayer dielectric film  24  in the slit parts  18   a  and the buried source layer BSL as indicated by an arrow A 4 . 
     In this way, according to the present embodiment, even when film peeling occurs in the ±X directions between the stacked body  2   a  and the buried source layer BLS, the film peeling can be guided to the direction (the −Z direction) indicated by the arrows A 1  to A 4  due to the slit parts  18   a  and  18   b  provided in the edge seal region Rea to suppress progression of the film peeling toward the chip body region Rc. 
     Since film peeling is likely to occur particularly between the stacked body  2   a  and the buried source layer BSL, it suffices to provide the slit parts  18   a ,  18   b ,  310   a , and  310   b  to correspond to at least the stacked body  2   a . That is, the slit parts  18   a ,  18   b ,  310   a , and  310   b  in the edge seal region Res or the kerf region Rk are provided at the outer edge of the stacked body  2  on the body part  19  in such a pattern that overlaps with at least the stacked body  2   a  as viewed from the body part  19 . For example, when the stacked body  2   a  is provided only on a portion of the periphery part  17  facing a certain side of the periphery of the body part  19 , it suffices to provide the slit parts  18   a ,  18   b ,  310   a , and  310   b  in the portion of the periphery part  17  facing this side. When the stacked body  2   a  is provided discontinuously in the manner of islands on the periphery part  17 , it suffices to similarly provide the slit parts  18   a ,  18   b ,  310   a , and  310   b  discontinuously in the manner of islands in the periphery part  17 . When the stacked body  2   a  is provided continuously on the periphery part  17  entirely therearound, it is preferable that the slit parts  18   a ,  18   b ,  310   a , and  310   b  be also continuously provided entirely around the periphery part  17 . 
     The slit parts  18   a ,  18   b ,  310   a , and  310   b  can be easily formed when a processing pattern for the buried source layer BSL (the conductive layer  12  and the semiconductor part  13 ) is changed. Therefore, detailed explanations of the manufacturing method of the semiconductor device according to the present embodiment are omitted. 
     Second Embodiment 
       FIG. 9A  is a sectional view illustrating a configuration example of a semiconductor device according to a second embodiment. In the second embodiment, a stacked body  2   b  is provided as a third stacked structure in the edge seal region Res and portions of the stacked body  2   b  are embedded in the slit parts  18   a  and  18   b.    
     The stacked body  2   b  is provided above the slit parts  18   a  and  18   b  and has a stacked structure in which the insulating layers (for example, silicon oxide films)  22  and the sacrificial films (for example, silicon nitride films)  23  are alternately stacked. The stacked body  2   b  in which the insulating layers  22  and the sacrificial films  23  are alternately stacked is filled in the slit parts  18   a  and  18   b . The stacked structure itself of the stacked body  2   b  can be same as that of the stacked body  2   a . Therefore, the stacked body  2   b  can be formed in the same manner as that of the stacked body  2   a . The staked body  2   b  is also provided along at least one portion of the outer edge of the stacked body  2  on the body part  19 . For example, the stacked body  2   b  is provided only on a portion of the periphery part  17  facing a certain side of the periphery of the body part  19  in some cases. The stacked body  2   b  is sometimes provided discontinuously in the manner of islands on the periphery part  17 . The stacked body  2   b  may be provided to correspond to the stacked body  2   a  at the periphery of the body part  19 . Alternatively, the stacked body  2   b  may be continuously provided entirely around the periphery of the body part  19 . In a case in which the slit parts  18   a  and  18   b  are provided in a region of the periphery part  17  where the stacked body  2   b  is not provided, an insulating film (for example, a silicon oxide film) is embedded in the slit parts  18   a  and  18   b.    
     In the second embodiment, the material film (for example, a silicon oxide film) filled in the slit parts  18   a  and  18   b  is removed before the insulating layers  22  and the sacrificial films  23  are alternately deposited. That is, the inner portions of the slit parts  18   a  and  18   b  are voided. Accordingly, when the insulating layers  22  and the sacrificial films  23  are alternately deposited, the insulating layers  22  and the sacrificial films  23  are stacked also in the slit parts  18   a  and  18   b  and filled therein. 
     Misalignments of layers are produced in the stacked structure of the insulating layers  22  and the sacrificial films  23  provided above the slit parts  18   a  and  18   b  due to the filing of the stacked structure of the insulating layers  22  and the sacrificial films  23  in the inner portions of the slit parts  18   a  and  18   b . However, these misalignments of layers do not affect the characteristics of the semiconductor storage device  100   a . Other configurations of the second embodiment may be identical to corresponding ones of the first embodiment. 
     The second embodiment can achieve effects identical to those of the first embodiment. Furthermore, portions of the insulating layers  22  and the sacrificial films  23  are stacked in the horizontal direction and boundary portions between the insulating layer  22  and the sacrificial film  23  extend in the Z direction on inner side surfaces of the slit parts  18   a  and  18   b . Therefore, film peeling can be guided to the −Z direction between the inner side surfaces of the slit parts  18   a  and  18   b  and the stacked body  2   b  and can be guided to the −Z direction also by the interfaces between the insulating layer  22  and the sacrificial film  23 . Therefore, progression of film peeling toward the chip body region Rc can be further suppressed. 
     (Modification) 
       FIG. 9B  is a sectional view illustrating a configuration example of a semiconductor device according to a modification of the second embodiment. In the second embodiment described above, the stacked body  2   b  is filled in both the slit parts  18   a  and  18   b . However, the stacked body  2   b  may be filled only in either the slit parts  18   a  or  18   b  as in the present modification. In this case, an insulating film (for example, a silicon oxide film) is embedded in the other slit parts  18   a  or  18   b . Other configurations of the present modification may be identical to corresponding ones of the second embodiment. Therefore, the present modification can achieve effects identical to those of the second embodiment. 
     Third Embodiment 
       FIG. 10A  is a sectional view illustrating a configuration example of a semiconductor device according to a third embodiment. In the third embodiment, a stacked body  2   c  is provided as a third stacked structure in the edge seal region Res and portions of the stacked body  2   c  are embedded in the slit parts  18   a  and  18   b.    
     The stacked body  2   c  is provided above the slit parts  18   a  and  18   b  and has a stacked structure (OWOW) in which the insulating layers (for example, a silicon oxide film)  22  and the electrode films (for example, tungsten)  21  are alternately stacked. The stacked body  2   c  in which the insulating layers  22  and the electrode films  21  are alternately stacked is filled in the slit parts  18   a  and  18   b . The stacked structure itself of the stacked body  2   c  can be the same as that of the stacked body  2  being the first stacked structure provided in the chip body region Rc. Therefore, the stacked body  2   c  can be formed in the same manner as that of the stacked body  2 . The stacked body  2   c  is provided along at least one portion of the outer edge of the stacked body  2  on the body part  19 . For example, the stacked body  2   c  is provided only on a portion of the periphery part  17  facing a certain side of the periphery of the body part  19  in some cases. The stacked body  2   c  is sometimes provided discontinuously in the manner of islands on the periphery part  17 . The stacked body  2   c  may be provided to correspond to the stacked body  2   a  at the periphery of the body part  19 . Alternatively, the stacked body  2   c  may be continuously provided entirely around the periphery of the body part  19 . In a case in which the slit parts  18   a  and  18   b  are provided in a region of the periphery part  17  where the stacked body  2   c  is not provided, an insulating film (for example, a silicon oxide film) is embedded in the slit parts  18   a  and  18   b.    
     Since the stacked body  2   c  is formed at the same time as the stacked body  2 , the deep slits ST and the columnar parts CLHR are provided in the stacked body  2   c . The deep slits ST are used at the time of replacement of the sacrificial films  23  with the electrode films  21 , and the sacrificial films  23  are replaced with the electrode films  21  through the deep slits ST. In this replacing process, the columnar parts CLHR function as support members for holding voids formed when the sacrificial films  23  are removed from the stacked body  2   c . For example, a conductive body (a metal material) being a second conductive film that is electrically insulated from the stacked body  2   c  by an insulator and that is electrically connected to the buried source layer BSL is filled in the deep slits ST similarly to the plate-like parts  3  in  FIG. 1B . The deep slits ST in the stacked body  2   c  also have a same function as that of the crack stopper CST in  FIG. 8 , as well as being used in the replacing process, particularly when continuously provided entirely around the periphery of the body part  19  along with the stacked body  2   c.    
     In the third embodiment, the material film (for example, a silicon oxide film) filled in the slit parts  18   a  and  18   b  is removed before the insulating layers  22  and the sacrificial films  23  are alternately deposited. That is, the inner portions of the slit parts  18   a  and  18   b  are voided. Accordingly, when the insulating films  22  and the sacrificial films  23  are alternately deposited, the insulating films  22  and the sacrificial films  23  are stacked also in the slit parts  18   a  and  18   b  and filled therein. The sacrificial films  23  are then replaced with the electrode films  21  in the replacing process, whereby the stacked body  2   c  in which the insulating layers  22  and the electrode films  21  are alternately stacked is filled in the slit parts  18   a  and  18   b.    
     The filling of the stacked structure including the insulating layers  22  and the electrode films  21  in the inner portions of the slit parts  18   a  and  18   b  produces misalignments of layers in the stacked structure of the insulating layers  22  and the electrode films  21  above the slit parts  18   a  and  18   b . However, these misalignments of layers do not affect the characteristics of the semiconductor storage device  100   a . Other configurations of the third embodiment may be identical to corresponding ones of the first embodiment. 
     The third embodiment can achieve effects identical to those of the first embodiment. Furthermore, portions of the insulating layers  22  and the electrode films  21  are stacked in the horizontal direction and boundary portions between the insulating layer  22  and the electrode film  21  extend in the Z direction on the inner side surfaces of the slit parts  18   a  and  18   b . Therefore, film peeling can be guided to the −Z direction between the inner side surfaces of the slit parts  18  and  18   b  and the stacked body  2   c , and can be guided to the −Z direction also by the interfaces between the insulating layer  22  and the electrode film  21 . Accordingly, progression of the film peeling toward the chip body region Rc can be further suppressed. 
     The stacked structure (OWOW) including the insulating layers (for example, silicon oxide films)  22  and the electrode films (for example, tungsten)  21  is expected to have a higher effect of suppressing progression of the film peeling than the stacked structure (ONON) including the insulating layers (silicon oxide films)  22  and the sacrificial films (silicon nitride films)  23  being the third insulating layers. This is because, for example, an interface between tungsten and a silicon dioxide film has higher adhesion than an interface between a silicon nitride film and a silicon oxide film. Therefore, use of the stacked structure (OWOW) including the insulting layers (for example, silicon oxide films)  22  and the electrode films (for example, tungsten)  21  as the stacked body  2   c  can suppress progression of film peeling more than in the second embodiment. 
     (Modification) 
       FIG. 10B  is a sectional view illustrating a configuration example of a semiconductor device according to a modification of the third embodiment. In the third embodiment described above, the stacked body  2   c  is filled in both the slit parts  18   a  and  18   b . However, the stacked body  2   c  may be filled only in either the slit parts  18   a  or  18   b  as in the present modification. In this case, an insulating film (for example, a silicon oxide film) is filled in the other slit parts  18   a  or  18   b . Other configurations of the present modification may be identical to corresponding ones of the third embodiment. Therefore, the present modification can achieve effects identical to those of the third embodiment. 
     Fourth Embodiment 
       FIG. 11  is a sectional view illustrating a configuration example of a semiconductor device according to a fourth embodiment. In the fourth embodiment, the stacked body  2   c  in the edge seal region Res and the stacked body  2   a  in the kerf region Rk are connected. In this case, the deep slits ST are formed in the edge seal region Res and are not formed in the kerf region Rk. Accordingly, after the stacked body  2   a  is formed in the edge seal region Res and the kerf region Rk, the sacrificial films  23  in the edge seal region Res are replaced with the material of the electrode films  21  through the deep slits ST in the replacing process. Meanwhile, the sacrificial films  23  in the kerf region Rk remain as they are without being replaced. In this way, even when the stacked body  2   c  in the edge seal region Res and the stacked body  2   a  in the kerf region Rk are connected, the sacrificial films  23  can be replaced with the electrode films  21  only in the stacked body  2   c  in the edge seal region Res. 
     In this case, the slit parts  18   a  and  18   b  are filled with the stacked body  2   c  including the insulating layers  22  and the electrode films  21 . Other configurations of the fourth embodiment may be identical to corresponding ones of the third embodiment. Therefore, the fourth embodiment can achieve effects identical to those of the third embodiment. 
     In the fourth embodiment, the stacked body  2   a  and the stacked body  2   c  are continuous as one stacked body. Therefore, for example, if the stacked body (for example, ONON)  2   a  is lost at the end portion  1   e  in  FIG. 4  at the time of dicing, the stacked body (for example, OWOW)  2   c  appears at the outer edge of a singulated semiconductor chip. In this case, only the stacked body  2   c  is formed as the second stacked structure along at least one portion of the outer edge of the stacked body  2  (the first stacked structure) on the body part  19 , and the slit parts  18   a  and  18   b  are arranged under the stacked body  2   c  as the second stacked structure. The stacked body  2   c  itself being the second stacked structure is embedded in the slit parts  18   a  and  18   b.    
     In the fourth embodiment, the deep slits ST extending in the stacked body  2   c  in the stacking direction (the Z direction) are provided. The deep slits ST are configured to be filled with a conductive body (a second conductive film) electrically insulated from the stacked body  2   c  by an insulator on inner walls of the deep slits ST similarly to the plate-like parts  3  in  FIG. 1B  as described above and extend in the Y direction in the stacked body  2   c  in a planar view seen from the Z direction. It suffices that the deep slits ST are provided in the stacked body  2   c  where the replacing process is performed in the periphery part  17 , and the deep slits ST do not need to be provided in a region of the periphery part  17  where the stacked body  2   c  is not arranged. 
     Fifth Embodiment 
       FIG. 12  is a sectional view illustrating a configuration example of a semiconductor device according to a fifth embodiment. The fifth embodiment is the same as the fourth embodiment in that the stacked body  2   c  in the edge seal region Res and the stacked body  2   a  in the kerf region Rk are connected. Meanwhile, the stacked body (for example, OWOW)  2   c  is not provided into the slit parts  18   b  and the stacked body  2   a  (for example, ONON) is provided into the slit parts  18   b  in the fifth embodiment. In this case, the deep slits ST are formed near the slit parts  18   a  in the edge seal region Res and are not formed near the slit parts  18   b  and in the kerf region Rk. Accordingly, after the stacked body  2   a  is formed in the edge seal region Res and the kerf region Rk, the sacrificial films  23  near the slit parts  18   a  in the edge seal region Res are replaced with the material of the electrode films  21  through the deep slits ST in the replacing process. Meanwhile, the sacrificial films  23  near the slit parts  18   b  and in the kerf region Rk remain as they are without being replaced. Accordingly, the slit parts  18   a  are filled with the stacked body (for example, OWOW)  2   c  including the insulating layers  22  and the electrode films  21  and the slit parts  18   b  are filled with the stacked body (for example, ONON)  2   a  including the insulating layers  22  and the sacrificial films  23 . Other configurations of the fifth embodiment may be identical to corresponding ones of the third embodiment. Therefore, the fifth embodiment can achieve effects identical to those of the third embodiment. 
     As described above, the stacked bodies  2   a  and  2   c  may be connected to each other. In this case, the boundary between the stacked bodies  2   a  and  2   c  can be controlled according to the positions of the deep slits ST. 
     Also in the fifth embodiment, similarly to the fourth embodiment, the stacked body  2   a  and the stacked body  2   c  are continuous as one stacked body. Further, also similarly to the fourth embodiment, the deep slits ST are provided in the stacked body  2   c.    
     While certain embodiments have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the inventions. Indeed, the novel methods and systems described herein may be embodied in a variety of other forms; furthermore, various omissions, substitutions and changes in the form of the methods and systems described herein may be made without departing from the spirit of the inventions. The accompanying claims and their equivalents are intended to cover such forms or modifications as would fall within the scope and spirit of the inventions.