Abstract:
A DRAM cell with a self-aligned gradient P-well and a method for forming the same. The DRAM cell includes (a) a semiconductor substrate; (b) an electrically conducting region including a first portion, a second portion, and a third portion; (c) a first doped semiconductor region wrapping around the first portion, but electrically insulated from the first portion by a capacitor dielectric layer; (d) a second doped semiconductor region wrapping around the second portion, but electrically insulated from the second portion by a collar dielectric layer. The second portion is on top of and electrically coupled to the first portion, and the third portion is on top of and electrically coupled to the second portion. The collar dielectric layer is in direct physical contact with the capacitor dielectric layer. When going away from the collar dielectric layer, a doping concentration of the second doped semiconductor region decreases.

Description:
This application is a Divisional of Ser. No. 11/308,404, filed Mar. 22, 2006 now U.S. Pat. No. 7,294,543. 

   BACKGROUND OF THE INVENTION 
   1. Technical Field 
   The present invention relates to DRAM (Dynamic Random Access Memory) cells, and more particularly, to DRAM cells with self-aligned gradient wells. 
   2. Related Art 
   In a typical trench DRAM cell there exists a VPT (vertical parasitic transistor) that causes a leakage current during the normal operating of the DRAM cell. Therefore, there is a need for a structure and a method for forming the same of a DRAM cell in which the leakage current flowing through the VPT is reduced without compromising other device characteristics. 
   SUMMARY OF THE INVENTION 
   The present invention provides a semiconductor structure, comprising (a) a semiconductor substrate; (b) an electrically conducting region in the semiconductor substrate, wherein the electrically conducting region includes a first portion, a second portion, and a third portion, and wherein the second portion is on top of and electrically coupled to the first portion, and the third portion is on top of and electrically coupled to the second portion; (c) a first doped semiconductor region (i) in the semiconductor substrate, (ii) wrapping around side walls and a bottom wall of the first portion of the electrically conducting region, but (iii) electrically insulated from the electrically conducting region by a capacitor dielectric layer; and (d) a second doped semiconductor region (i) in the semiconductor substrate, (ii) wrapping around side walls of the second portion, but (iii) electrically insulated from the second portion by a collar dielectric layer, where in the second doped semiconductor region is self-aligned to the first doped semiconductor region, wherein the collar dielectric layer is in direct physical contact with the capacitor dielectric layer, and wherein when going from an interfacing surface of the collar dielectric layer and the second doped semiconductor region and away from the collar dielectric layer, a doping concentration of the second doped semiconductor region decreases. 
   The present invention also provides a semiconductor structure, comprising (a) a semiconductor substrate; (b) an electrically conducting region in the semiconductor substrate, wherein the electrically conducting region includes a first portion, a second portion, and a third portion, and wherein the second portion is on top of and electrically coupled to the first portion, and the third portion is on top of and electrically coupled to the second portion; (c) a first doped semiconductor region (i) in the semiconductor substrate, (ii) wrapping around side walls and a bottom wall of the first portion, but (iii) electrically insulated from the first portion by a capacitor dielectric layer; and (d) a second doped semiconductor region (i) in the semiconductor substrate, (ii) wrapping around side walls of the second portion, but (iii) electrically insulated from the second portion by a collar dielectric layer, wherein the second doped semiconductor region is self-aligned to the first doped semiconductor region, wherein the collar dielectric layer is in direct physical contact with the capacitor dielectric layer, wherein when going from an interfacing surface of the collar dielectric layer and the second doped semiconductor region and away from the collar dielectric layer, a doping concentration of the second doped semiconductor region decreases, wherein a thickness of the capacitor dielectric layer is less than a thickness of the collar dielectric layer, wherein the electrically conducting region comprises dopants having a first doping polarity, wherein the first doped semiconductor region comprises dopants having the first doping polarity, and wherein the second doped semiconductor region comprises dopants having a second doping polarity which is opposite to the first doping polarity. 
   The present invention provides a semiconductor fabrication method, comprising providing a semiconductor structure which includes (a) a semiconductor substrate, (b) a deep trench in the semiconductor substrate, wherein the deep trench comprises a side wall and a bottom wall, and wherein the side wall comprises an upper side wall portion and a lower side wall portion; forming a first doped semiconductor region and a second doped semiconductor region, wherein the first doped semiconductor region (i) wraps around the lower side wall portion of the deep trench and (ii) abuts the bottom wall and the lower side wall portion of the deep trench, wherein the second doped semiconductor region wraps around and abuts the upper side wall portion of the deep trench, wherein the second doped semiconductor region is self-aligned to the first doped semiconductor region, wherein the first doped semiconductor region comprises dopants of a first doping polarity, wherein the second doped semiconductor region comprises dopants of a second doping polarity which is opposite to the first doping polarity; and forming a dielectric layer and an electrically conducting region in the deep trench, wherein the dielectric layer is on the side wall and the bottom wall of the deep trench, wherein the dielectric layer comprises a capacitor dielectric portion and a collar dielectric portion, wherein the electrically conducting region comprises a first portion, a second portion, and a third portion, wherein the second portion is on top of and electrically coupled to the first portion, and the third portion is on top of and electrically coupled to the second portion, and wherein when going from an interfacing surface of the collar dielectric portion and the second doped semiconductor region and away from the collar dielectric portion, a doping concentration of the second doped semiconductor region decreases. 
   The present invention also provides a semiconductor fabrication method, comprising providing a semiconductor structure which includes (a) a semiconductor substrate, (b) an electrically conducting region in the semiconductor substrate, wherein the electrically conducting region includes a first portion, a second portion, and a third portion, and wherein the second portion is on top of and electrically coupled to the first portion, and the third portion is on top of and electrically coupled to the second portion, (c) a first doped semiconductor region (i) in the semiconductor substrate, (ii) wrapping around side walls and a bottom wall of the first portion, but (iii) electrically insulated from the first portion by a capacitor dielectric layer, and (d) a second doped semiconductor region (i) in the semiconductor substrate, (ii) wrapping around side walls of the second portion, but (iii) electrically insulated from the second portion by a collar dielectric layer, wherein the collar dielectric layer is in direct physical contact with the capacitor dielectric layer, and wherein when going from an interfacing surface of the collar dielectric layer and the second doped semiconductor region and away from the collar dielectric layer, a doping concentration of the second doped semiconductor region decreases 
   The present invention provides a DRAM cell (and a method for operating the same) with a gradient P-well self-aligned to the buried plate to reduce the leakage current through the VPT (vertical parasitic transistor). 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
       FIGS. 1-25  show a first fabrication process of a DRAM cell with a self-aligned gradient P-well, in accordance with embodiments of the present invention. 
       FIGS. 26-30  show a second fabrication process of another DRAM cell with a self-aligned gradient P-well, in accordance with embodiments of the present invention. 
   

   DETAILED DESCRIPTION OF THE INVENTION 
     FIGS. 1-25  show a first fabrication process for forming a DRAM (Dynamic Random Access Memory) cell structure  100 , in accordance with embodiments of the present invention. 
   More specifically, with reference to  FIG. 1 , in one embodiment, the first fabrication process starts out with a semiconductor substrate  110  such as a lightly doped silicon substrate. Other suitable alternative types of substrates include germanium (Ge), silicon germanium (SiGe), silicon carbide (SiC), and those consisting essentially of one or more compound semiconductors such as gallium arsenic (GaAs), gallium nitride (GaN), and indium phosphoride (InP). Alternatively, the substrate has a semiconductor-on-insulator type structure, e.g., a silicon-on-insulator (SOI) substrate. 
   Next, in one embodiment, a pad oxide layer  120  is formed on top of the semiconductor substrate  110  by thermal oxidation. Alternatively, the pad oxide layer  120  can be formed by using a deposition technique such as CVD (Chemical Vapor Deposition) method. 
   Next, with reference to  FIG. 2 , in one embodiment, a pad nitride layer  210  is formed on top of the structure  100  of  FIG. 1  using CVD method. 
   Next, with reference to  FIG. 3 , in one embodiment, a deep trench  310  is formed in the semiconductor substrate  110 . Illustratively, the deep trench  310  is formed by (i) depositing a hardmask layer such as boron-doped oxide (not shown) on top of the pad nitride layer  210  ( FIG. 2 ), (ii) patterning the deposited hardmask layer, pad nitride layer  210 , and pad oxide layer  120 , and (iii) etching the silicon substrate by a RIE (Reactive Ion Etching) process selective to the hardmask layer. The hardmask layer can be stripped after the deep trench  310  is formed or in any suitable later process steps. 
   Next, with reference to  FIG. 4 , in one embodiment, a first dopant source layer  410  containing a first doping polarity is formed on top of the structure  100  of  FIG. 3  including on side walls and on a bottom wall of the deep trench  310  ( FIG. 3 ). Illustratively, an ASG (arsenic silicate glass) layer  410  with a thickness 50-1000 angstroms is formed by CVD or ALD (atomic layer deposition) method as the dopant source for N-type dopants, resulting in the structure  100  of  FIG. 4 . Alternatively, other materials such as oxide doped with phosphorus, antimony, or any combination of these dopants can be used as the dopant source for N-type dopants. 
   Next, with reference to  FIG. 5 , in one embodiment, the deep trench  130  is filled with a sacrificial material  510 . Preferably, the sacrificial material  510  is a polymer such as a resist or SiLK®, the latter of which is available from Dow Chemical. Illustratively, the sacrificial material  510  is formed by a conventional coating technique. 
   Next, in one embodiment, a top portion  510   a  of the sacrificial material  510  is recessed to a predetermined depth and a bottom portion  510   b  of the sacrificial material  510  still remains as shown in  FIG. 6 . A conventional RIE, CDE (chemical downstream etch), or other suitable process can be used for recessing the sacrificial material  510 . Hereafter, the bottom portion  510   b  of the sacrificial material  510  is referred to as a sacrificial material region  510   b.    
   Next, with reference to  FIG. 6 , in one embodiment, the exposed portion of the ASG layer  410  is removed by, illustratively, wet etching with an enchant containing hydrofluoric acid, resulting in the ASG region  410 ′ as shown in  FIG. 7 . 
   Next, with reference to  FIG. 7 , in one embodiment, the sacrificial material region  510   b , when it is a resist, is removed by, illustratively, wet etching with an enchant containing sulfuric acid and hydrogen peroxide, resulting in a trench  810  as shown in  FIG. 8 . Alternatively, the sacrificial material region  510   b  is removed by a dry etch process 
   Next, with reference to  FIG. 9 , in one embodiment, a second dopant source layer  910  is formed on top of the structure  100  of  FIG. 8  including side walls and a bottom wall of the trench  810  ( FIG. 8 ). Dopants in the second dopant source layer  910  have the opposite polarity to the doping polarity of dopants in the first dopant source layer  410 . Preferably, the dopant concentration in the second dopant source layer  910  is lower than the dopant concentration in the first dopant source layer  410  and the thickness of the second dopant source layer  910  is less than the thickness of the first dopant source layer  410  to facilitate the formation of self-aligned P-well and buried plate in later processes. Illustratively, a BSG (borosilicate glass) layer  910  with a thickness of 20-300 angstroms formed by CVD, ALD, or thermal deposition as the second dopant source layer. Alternatively, other suitable dopant source materials such as an oxide containing indium can be used. 
   Next, with reference to  FIG. 10 , in one embodiment, a cap layer  1010  is formed on top of the structure  100  including on side walls and on a bottom wall of the trench  810  ( FIG. 9 ). Illustratively, the cap layer  1010  is formed by CVD or ALD of silicon dioxide (SiO 2 ). 
   Next, in one embodiment, the structure  100  of  FIG. 10  is annealed at a high temperature (e.g., 700-1100° C.). As a result, arsenic dopants in the ASG region  410 ′ diffuse into the semiconductor substrate  110 , resulting in an N+ buried plate  1110 ; and boron dopants in the BSG layer  910  diffuse into the semiconductor substrate  110 , resulting in a gradient P-well  1120  which is self-aligned to the buried plate  1110 , as shown in  FIG. 11 . 
   In one embodiment, the ASG layer  410 ′ underneath the BSG layer  910  has a thickness greater than 400 angstroms prevents boron diffusion into the buried plate region  1110 , resulting in only arsenic diffusion into the buried plate region  1110 . 
   In another embodiment, the buried plate  1110  comprises both N-type dopants (coming from the ASG region  410 ′) and P-type dopants (coming from the BSG layer  910 ). In one embodiment, in the buried plate  1110 , the doping concentration of the N-type dopants is greater than the doping concentration of the P-type dopants. In other words, it is said that the buried plate  1110  electrically exhibits the N-type doping polarity. 
   In one embodiment, the doping concentration of the ASG region  410 ′ is greater than the doping concentration of the BSG layer  910 . 
   In one embodiment, the doping concentration of N-type dopants in the buried plate  1110  ranges preferably from 10 18  to 10 20 /cm 3  and more preferably from 10 19  to 5×10 19 /cm 3 . The doping concentration of P-type dopants in the buried plate region  1110 , if present, is preferably less than 20%, and more preferably less than 10% of the doping concentration of N-type dopants. The doping concentration of P-type dopants in the gradient P-well  1120  ranges preferably from 10 17  to 5×10 19 /cm 3  and more preferably from 5×10 17  to 5×10 18 /cm 3 . 
   Next, with reference to  FIG. 11 , in one embodiment, the cap layer  1010 , the BSG layer  910 , and the ASG region  410 ′ are removed by using wet etching with an etchant containing hydrofluoric acid, resulting in a trench  1210  as shown in  FIG. 12 . 
   Next, with reference to  FIG. 13 , in one embodiment, a capacitor dielectric layer  1310  is formed on top of the structure  100  of  FIG. 12  including on side walls and on a bottom wall of the trench  1210  ( FIG. 12 ). Illustratively, the capacitor dielectric layer  1310  comprises silicon nitride. In one embodiment, the capacitor dielectric layer  1310  is formed by CVD of silicon nitride followed by a high temperature anneal (e.g., 800-1100° C.) in an environment containing oxygen. Alternatively, other suitable dielectric such as oxide, oxynitride, and/or “high-k” (high dielectric constant) materials. 
   Next, with reference to  FIG. 14 , in one embodiment, a first conducting material (e.g., N+ polysilicon doped with arsenic, any metal such as tungsten, any conducting metallic compound such as tungsten silicide, or any other suitable conducting material) region  1410  is formed in the trench  1210  of  FIG. 13 . Illustratively, the first N+ polysilicon region  1410  is formed by CVD of a polysilicon layer (not shown) everywhere on top of the structure  100  (including in the trench  1210 ) of  FIG. 13 , and then (ii) optional planarization of the deposited polysilicon layer, e.g., by CMP (chemically mechanical polishing), until a top surface  1311  of the capacitor dielectric layer  1310  is exposed to the surrounding ambient as shown in  FIG. 14 . 
   Next, in one embodiment, a top portion  1410   a  of the first N+ polysilicon region  1410  is removed by, illustratively, RIE process, resulting in a bottom portion  1410   b  of the first N+ polysilicon region  1410 , and resulting in a trench  1510  as shown in  FIG. 15 . Hereafter the bottom portion  1410   b  is referred to as a first N+ polysilicon region  1410   b.    
   Illustratively, with reference to  FIG. 15 , a top surface  1411  of the first N+ polysilicon region  1410   b  is essentially at a same level (i.e., coplanar) as a top surface  1115  of the N+ buried plate  1110 . 
   Next, in one embodiment, the exposed portion of the capacitor dielectric layer  1310  is removed by, illustratively, wet etching, resulting in a capacitor dielectric region  1310 ′ as shown in  FIG. 16 . 
   Next, with reference to  FIG. 17 , in one embodiment, a collar layer  1710  is formed on top of the structure  100  of  FIG. 16  including on side walls and on a bottom wall of the trench  1510 . Illustratively, the collar layer  1710  comprises silicon oxide. In one embodiment, the collar layer  1710  is formed by thermal oxidation. In another embodiment, the collar layer  1710  is formed by a deposition technique such as CVD or ALD (atomic layer deposition). Yet in a third embodiment, the collar layer  1710  is formed by thermal oxidation followed by a deposition. A high temperature annealing process (e.g., 700-1100° C. for 2-200 minutes) may be performed, after the collar layer  1710  is formed by deposition, to densify the deposited collar layer  1710  and improve the integrity of trench structure. In one embodiment, the collar layer  1710  essentially contains no or substantially low dopant concentration for the reason that excessive dopants in the collar  1710  otherwise would diffuse into the p-well and into the trench and cause undesired dopant variation in these regions. It should be noted that a first thickness  1715  of the collar layer  1710  is equal or greater than a second thickness  1315  of the capacitor dielectric region  1310 ′. 
   Next, in one embodiment, a bottom portion  1713  and a portion  1714  of the collar layer  1710  are removed by, illustratively, RIE process such that the top surface  1411  of the first N+ polysilicon region  1410  and a top surface  213  of the pad nitride layer  210  are exposed to the surrounding ambient, and such that the collar layer  1710  still remains on the side walls of the trench  1510 , as shown in  FIG. 18 . 
   Next, with reference to  FIG. 19 , in one embodiment, a second conducting material (e.g., N+ polysilicon) region  1910  is formed in the trench  1510  of  FIG. 18 . Illustratively, the second N+ polysilicon region  1910  is formed by (i) CVD of a polysilicon layer (not shown) everywhere on top of the structure  100  (including in the trench  1510 ) of  FIG. 18 , and then (ii) optional planarization of the deposited polysilicon layer, e.g., by CMP, until the top surface  213  of the pad nitride layer  210  is exposed to the surrounding ambient, as shown in  FIG. 19 . 
   Next, in one embodiment, a top portion  1910   a  of the second N+ polysilicon region  1910  is removed by, illustratively, RIE process, resulting in a bottom portion  1910   b  of the second N+ polysilicon region  1910  as shown in  FIG. 20 . Hereafter, the bottom portion  1910   b  is referred to as the second N+ polysilicon region  1910   b . In one embodiment, a top surface  1911  of the second N+ polysilicon region  1910   b  is at a lower level than a top surface  115  of the semiconductor substrate  110 , as shown in  FIG. 20 . 
   Next, with reference to  FIG. 20 , in one embodiment, the exposed portion of the collar layer  1710  is removed by, illustratively, wet etching, resulting in a collar layer  1710 ′ and resulting in a trench  2010  as shown in  FIG. 21 . 
   Next, with reference to  FIG. 22 , in one embodiment, a third conducting material (e.g., N+ polysilicon) region  2210  is formed in the trench  2010  of  FIG. 21 . Illustratively, the third N+ polysilicon region  2210  is formed by (i) CVD of a polysilicon layer (not shown) everywhere on top of the structure  100  (including the trench  2010 ) of  FIG. 21 , (ii) optional planarization of the deposited polysilicon layer, e.g., by CMP, until the top surface  213  of the pad nitride layer  210  is exposed to the surrounding ambient; and then (iii) recess of the third N+ polysilicon region  2210  so that a top surface  2215  of the third N+ polysilicon region  2210  is at a same level with the top surface  115  of the semiconductor substrate  110 . 
   Next, in one embodiment, dopants of the third N+ polysilicon region  2210  diffuse into the semiconductor substrate  110  at subsequent high temperature (e.g., 700-1100° C.) processes, resulting in a buried strap region  2310  as shown in  FIG. 23 . 
   Next, with reference to  FIG. 24 , in one embodiment, an STI (shallow trench isolation) region  2410  is formed by conventional processes well known in the art. The pad nitride layer  210  and pad oxide layer  120  are removed before or after STI formation. 
   Next, with reference to  FIG. 25 , in one embodiment, a gate dielectric layer  2520 , a gate electrode  2530 , a first source/drain region  2510   a , its associated contact region  2560 , and a second source/drain region  2510   b  of an access transistor  2540  are formed by a conventional method, resulting in a DRAM cell which comprises a capacitor and the access transistor  2540 . It should be noted that the capacitor comprises a capacitor dielectric layer  1310 ′, a first capacitor electrode  1110  (which is the N+ buried plate  1110 ), a second capacitor electrode  1410   b + 1910   b + 2210  (which comprises the first N+ polysilicon region  1410   b , the second N+ polysilicon region  1910   b , and the third N+ polysilicon region  2210 ), and the buried strap region  2310  used to electrically connect the second capacitor electrode  1410   b + 1910   b + 2210  of the capacitor to the first source/drain region  2510   a  of the access transistor  2540 . 
   It should be noted that there is an unwanted VPT (Vertical Parasitic Transistor) comprising a substrate, a gate electrode, a gate dielectric layer, a channel region, a first source/drain region and a second source/drain region. More specifically, the substrate of the VPT is the semiconductor substrate  110 , the gate electrode of the VPT is the second N+ polysilicon region  1910   b , the gate dielectric layer of the VPT is the collar layer  1710 ′, the channel region of the VPT is the gradient P-well  1120 , the first source/drain region of the VPT is the N+ buried plate  1110 , and the second source/drain region of the VPT is the buried strap region  2310 . 
   It should be noted that doping concentration of the P-well  1120  is gradient, meaning that when going from the collar layer  1710 ′ outward, the doping concentration of the gradient P-well  1120  decreases. It should also be noted that the P-well is self-aligned to the buried plate  1110 . The formation of the gradient P-well  1120  (the channel region of the VPT), which has the highest doping concentration next to the collar layer  1710 ′, effectively raises the threshold voltage of the VPT. The gradient P-well by this invention reduces the leakage current flowing through the VPT without significantly increasing junction current leakage through the junction between the N+ buried plate  1110  and the gradient P-well  1120 . 
     FIGS. 26-30  show a second fabrication process for forming a DRAM cell structure  200 , in accordance with embodiments of the present invention. 
   With reference to  FIG. 26 , in one embodiment, the second fabrication process starts out with a structure  200 . Illustratively, the fabrication of the structure  200  of  FIG. 26  is similar to the fabrication of the structure  100  of  FIG. 15 . Preferably, the gradient P-well  1120  has a greater doping concentration in this embodiment than the first embodiment. Illustratively, the doping concentration in the gradient P-well  1120  is preferably ranges from 5×10 17 /cm 3  to 10 19 /cm 3  and more preferably ranges from 10 18  to 5×10 18 /cm 3 . 
   Next, in one embodiment, the exposed portion of the capacitor dielectric layer  1310  is removed by, illustratively, wet etching, resulting in the capacitor dielectric layer  1310 ″ as shown in  FIG. 27 . 
   Next, with reference to  FIG. 28 , in one embodiment, a second N+ polysilicon region  2810  is formed in the trench  1510  of  FIG. 27 . Illustratively, the second N+ polysilicon region  2810  is formed by (i) CVD of a polysilicon layer (not shown) everywhere on top of the structure  200  (including in the trench  2610 ) of  FIG. 27 , and then (ii) optional planarization of the deposited polysilicon layer, e.g., by CMP, until the top surface  211  of the pad nitride layer  210  is exposed to the surrounding ambient and then (iii) recess of the second N+ polysilicon region  2810  so that a top surface  2815  of the second N+ polysilicon region  2810  is at a same level with the top surface  115  of the semiconductor substrate  110 . 
   Next, in one embodiment, dopants of the second N+ polysilicon region  2810  diffuse into the semiconductor substrate  110  in the subsequent high temperature (e.g., 700-1100° C.) process, resulting in a buried strap region  2910  as shown in  FIG. 29 . 
   Next, with reference to  FIG. 30 , in one embodiment, an STI region  3040  is formed in the semiconductor substrate  110  by conventional processes well known in the art. The pad nitride layer  210  and pad oxide layer  120  are removed after STI formation. 
   Next, in one embodiment, a gate dielectric layer  3020 , a gate electrode  3030 , a first source/drain region  3010   a , its associated contact region  3060 , and a second source/drain region  3010   b  of an access transistor  3050  are formed by a conventional method, resulting in a DRAM cell which comprises a capacitor and the access transistor  3050 . It should be noted that the capacitor comprises a capacitor dielectric layer  1310 ″, a first capacitor electrode  1110  (which is the N+ buried plate  1110 ), a second capacitor electrode  1410   b + 2810  (which comprises the first N+ polysilicon region  1410   b , and the second N+ polysilicon region  2810 ), and the buried strap region  2910  used to electrically connect the second capacitor electrode  1410   b + 2810  of the capacitor to the first source/drain region  3010   a  of the access transistor  3050 . 
   Because of the gradient P-well  1120  which has the highest doping concentration next to the capacitor dielectric layer  1310 ″ and therefore effectively increases the threshold voltage of the VPT, the leakage current flowing through the VPT is significantly reduced without significantly increasing the junction leakage current. Furthermore, since the P-well  1120  in  FIG. 30  has a greater doping concentration than the P-well in the first embodiment, the threshold voltage of the VPT is further increased. Consequently, a collar layer like the collar layer  1710 ′ in  FIG. 25  (of the first fabrication process) can be eliminated. Besides, increasing too much the collar layer thickness is not applicable to trench technology with small ground-rules because the collar layer thickness is limited by the trench dimension. 
   In the embodiments described above, the doping polarities of the N+ buried plate  1110 , the first N+ polysilicon region  1410   b , the second N+ polysilicon region  1910   b , the third N+ polysilicon region  2210 , the buried strap region  2310 , the first and second source/drain region  2510   a ,  2510   b , the second N+ polysilicon region  2810 , the buried strap region  2910 , and the first and second source/drain region  3010   a ,  3010   b  are N type whereas the doping polarity of the gradient P-well  1120  is P type. Alternatively, the doping polarities of the buried plate  1110 , the first polysilicon region  1410   b , the second polysilicon region  1910   b , the third polysilicon region  2210 , the buried strap region  2310 , the first and second source/drain region  2510   a ,  2510   b , the second polysilicon region  2810 , the buried strap region  2910 , and the first and second source/drain region  3010   a ,  3010   b  can be P type whereas the doping polarity of the gradient well  1120  can be N type. 
   While particular embodiments of the present invention have been described herein for purposes of illustration, many modifications and changes will become apparent to those skilled in the art. Accordingly, the appended claims are intended to encompass all such modifications and changes as fall within the true spirit and scope of this invention.