KR20220036049A - Semiconductor dram Cell Structure and Manufacture Method Thereof - Google Patents

Abstract

The present invention discloses a DRAM cell comprising an asymmetric transistor coupled to a capacitor. The asymmetric transistor includes a drain region extending upward from the isolator region; A gate region extending upward from the gate dielectric or isolator; and a source region of the asymmetric transistor extending upwardly from the first portion of the isolation layer. The upward extension direction of the drain region, gate region, and source region is perpendicular or substantially perpendicular to the original silicon surface. Moreover, the capacitor is formed to be partially recessed and the isolation layer is located within the recess. A capacitor extends upward from the second portion of the isolation layer. It is perpendicular or substantially perpendicular to the silicon surface in the upwardly extending direction of the upright portion of the capacitor electrode, the third portion of the insulating layer, and the counter electrode.

Description

Semiconductor DRAM cell structure and manufacturing method {Semiconductor dram Cell Structure and Manufacture Method Thereof}

The present invention relates to DRAM, and more particularly to a DRAM cell having a transistor with three terminals self-aligned in parallel and a low-leakage capacitor.

This application is related to U.S. Provisional Application No. 62/824,315, filed March 27, 2019, U.S. Provisional Application No. 62/818,753, filed March 15, 2019, and U.S. Provisional Application No. 62/, filed April 3, 2019. 828,485, the contents of which are incorporated herein by reference.

To create a microelectronics system, logic (or System on Chip (SOC)) functions and memory (SRAM, DRAM, Flash NAND/NOR, etc.) functions are stored on a single silicon die or on separate chips. A combination of these needs to be combined for effective and efficient implementation. One of the most difficult challenges is how to transfer large amounts of data between logic circuits and DRAM. There is a "DRAM Wall" which means that the data rate provided by DRAM cannot keep up with the bandwidth required by the logic circuit. The challenge is increasing as the processes, transistors, and interconnect systems of logic circuits scale much faster than DRAM scales. For example, the process node for each generation of logic circuit technology with transistors is approaching 7nm to 5nm, while the DRAM processing node is progressing much more slowly, from 20nm to 15nm. As a result, many problems - for example, those related to too many interfaces, power and heat losses, and noise - are multiplying and solutions are lacking.

Therefore, there is a need to provide effective DRAM cells that closely and optimally synchronize logic elements/circuits and DRAM cells/circuits.

The invention described here is to create an effective DRAM cell that accelerates the DRAM migration path between logic circuits and DRAM much easier and faster, as logic technology migration follows Moore's Law requirements. The invention also reduces technology/chip migration costs for both logic and DRAM.

One object of the invention is to provide a first conductive region extending upward and downward from the silicon surface, a gate structure over the silicon surface and extending upward from the silicon surface, a second conductive region extending upward and downward from the silicon surface, a gate. a channel region underlying the structure and in contact with the first conductive region and the second conductive region, a recess formed beneath the silicon surface, and an isolation layer located within the recess, wherein the isolation layer is recessed and covers the first sidewall of the recess. a capacitor comprising a first portion extending upward from the bottom wall of the portion, a second portion covering the bottom surface of the recess, and extending upward from the silicon surface and downward from the silicon surface to the second portion of the isolation layer. To provide a DRAM cell structure including. The upward extension direction of the first conductive region, gate structure, and second conductive region is perpendicular or substantially perpendicular to the silicon surface.

According to one aspect of the invention, the capacitor includes a first electrode comprising a connecting portion in contact with a second conductive region and an upright portion extending upwardly from the second portion of the isolating layer, an insulating layer comprising a third portion and a fourth portion covering the second portion of the insulating layer, and a second electrode extending upwardly from the fourth portion of the insulating layer. wherein the insulating layer is positioned between the first electrode and the second electrode, and the upright portion of the upright portion of the first electrode, the third portion of the insulating layer, and the upwardly extending direction of the second electrode are perpendicular to or substantially perpendicular to the silicon surface. It is vertical. Moreover, the DRAM cell structure further includes an isolator between the upright portion of the first electrode and the first portion of the isolation layer, wherein the upper surface of the isolator is lower than the upper surface of the second conductive region and the first electrode The connecting portion covers the upper surface of the isolator.

According to another aspect of the invention, the insulating layer further includes a fifth portion in contact with the connecting portion of the first electrode, wherein the fifth portion of the insulating layer, the connecting portion of the first electrode, and the upper surfaces of the second electrode are , no lower than the top surface of the gate structure. Moreover, the fifth part of the insulating layer, the connecting part of the first electrode, and the upper surfaces of the second electrode are aligned along the horizontal plane.

According to another aspect of the invention, the top surfaces of the first conductive region and the second conductive region are lower or no lower than the top surface of the gate structure. Additionally, the upper surfaces of the first conductive region and the second conductive region are aligned along the horizontal plane.

According to another aspect of the invention, the upper surface of the first conductive region is higher than the silicon surface and the first conductive region extends downward from the silicon surface to the first isolator region. Moreover, the first conductive region includes a lower portion and an upper portion vertically stacked over the lower portion, with the lower portion contacting the channel region and the first isolator region.

According to another aspect of the invention, the upper surface of the second conductive region is higher than the silicon surface and the second conductive region extends downward from the silicon surface to the first portion of the isolation layer. And, the second conductive region includes a lower portion and an upper portion vertically stacked over the lower portion, with the lower portion in contact with the channel region and the first portion of the isolation layer.

According to another aspect of the invention, the shape or size of the first conductive region is different from the shape or size of the second conductive region. According to another aspect of the invention, the DRAM cell structure further includes a spacer over the silicon surface and covering at least two sidewalls of the gate structure, where the first conductive region and the second conductive region are in contact with the spacer.

According to another aspect of the invention, the DRAM cell structure further includes an isolator derived from a lower portion of the second conductive region and from a first portion of the isolation layer. And, the isolator includes an oxide material, the isolation layer includes an oxide material, and the second conductive region includes a silicon material.

These and other objects of the present invention will no doubt be apparent to those skilled in the art after reading the following detailed description of the preferred embodiments shown in the various figures and drawings.

Figures 1A and 1B respectively show cross-sectional views of the proposed new DRAM cell structure.
Figure 2a shows a cross-sectional view following a first processing step using a transistor gate.
Figure 2b shows a cross-sectional view following an etch step to remove the isolator on the drain region.
Figure 3a shows a cross-sectional view following the etching steps to create a recess in the drain region and the formation of an isolation layer inside the recess.
Figure 4a shows a cross-sectional view following the formation stage of the silicon layer on the isolation layer inside the recess according to Figure 3a.
Figure 4b shows a cross-sectional view following the formation steps of the vertical drain region (VTD).
Figure 5a shows a cross-sectional view following the steps in forming a flat silicon surface.
Figure 5b shows a cross-sectional view following the photolithographic patterning steps for subsequent capacitor formation.
Figure 6A shows a cross-sectional view following an etch step to remove material within the capacitor region.
Figure 6b shows a cross-sectional view following the etching steps to create a recess in the capacitor area.
Figure 7 shows a cross-sectional view along the stages of formation of the oxide layer surrounding the four side walls and bottom surface of the recess in the capacitor region.
Figure 8 shows a cross-sectional view following the formation steps to fill the SOG layer in the recess in the capacitor area at the designed height.
Figure 9 shows a cross-sectional view following an etch step to remove the exposed oxide layer on top of the recess in the capacitor region.
Figure 10 shows a cross-sectional view following the formation steps of the vertical source region (VTS).
Figure 11 shows a cross-sectional view following steps for removing SOG material from a recess in the capacitor area.
Figure 12a shows a cross-sectional view following the formation steps for growing the oxide layer to wrap the VTS and the oxide layer surrounding the four side walls and bottom surface of the recess in the capacitor region according to the second embodiment of the invention.
Figure 12b shows a cross-sectional view following the formation steps for depositing a nitride layer wrapping the VTS and an oxide layer surrounding the four side walls and bottom surface of the recess in the capacitor region according to the first embodiment of the present invention.
Figure 13a shows a cross-sectional view following an etch step to expose the top silicon region of the VTS according to Figure 12a.
Figure 13b shows a cross-sectional view following an etching step to leave nitride spacers surrounding the four side walls of the recess in the capacitor region according to Figure 12b.
Figure 14a shows a cross-sectional view following the formation stage of the metal layer with connections on the upper exposed VTS region according to Figure 13a.
Figure 14b shows a cross-sectional view following the formation step of the metal layer with connections on the upper exposed VTS region according to Figure 13b. 13B.
Figure 15 shows a cross-section following a metal etch-back step forming four pillars on the sidewalls but without connection of these pillars at the bottom of the recess in the capacitor area.
Figure 16 shows a cross-sectional view following the forming steps for filling the SOG material in the recess in the capacitor area.
Figure 17 shows a cross-sectional view following an etching step to remove the upper portion of the SOG pillar for subsequent formation of the counter electrode plate region.
Figure 18 shows a cross-sectional view following a more complete etch step of a well-defined counter electrode plate area.
Figure 19 shows a cross-sectional view following the forming steps for filling the high-k dielectric insulator after removing the SOG filler in the recess in the capacitor region.
Figure 20 shows a cross-sectional view following the forming steps for a metal interconnection.
FIG. 21A shows a cross-sectional view of the DRAM cell structure of FIG. 1A along with additional descriptions of most components.
FIG. 21B shows a cross-sectional view of the DRAM cell structure of FIG. 1B along with additional descriptions of most components.

The detailed description of the embodiments described below of the disclosed devices and methods is presented herein by way of example and not by way of limitation, with reference to the drawings. Although specific embodiments have been shown and described in detail, it should be understood that various changes and modifications may be made without departing from the scope of the appended claims. The scope of the present invention is in no way limited to the number of components, the materials of the components, the shape of the components, the relative arrangement of the components, etc., and is simply disclosed as an example of an embodiment of the present invention.

1A and 1B, which show two invented DRAM cell structures, an invented DRAM cell structure (named WU cell) by a new well-designed silicon integrated circuit processing method is introduced. This WU cell structure has a drain region (2) used as a bit-line contact (3) shared with the adjacent cell transistor (4) and a counter electrode (counter-electrode) shared with the neighboring cell capacitor (10). There is a source region (5) connected to the capacitor (6), with a storage-electrode pillar (7) as a layer of high-k insulator (8) from the electrode (9). It has a transistor (Q1). Conductor line 11 (can be metal, n+ doped polysilicon, polycide, etc.) is connected to the open conductive region of contact 3 of drain region 2. In one embodiment, the drain region is a vertical drain region that extends upward from isolator region 32 and the top of isolator region 32 is lower than silicon surface 12. Source region 5 is a vertical source region extending upward from isolation layer 71 , the top of isolation layer 71 being lower than silicon surface 12 . Moreover, the gate region 1 of the transistor Q1 also extends upward from the gate dielectric insulator 13, and the gate region 1 is a type of vertical gate. The storage electrode pillar 7 has a vertical portion extending upward from the isolation layer 71, and the counter electrode 9 is a vertical counter electrode extending upward from the high-k dielectric constant insulator 8. The high-k dielectric constant insulator 8 also includes a vertical portion extending upward from the isolation layer 71 . The silicon surface may be the silicon substrate surface when the transistor is a planar transistor, or the top surface of a fin structure when the new transistor is a FinFET or tri-gate transistor.

Therefore, the direction of upward extension of the gate/drain/source regions is perpendicular or substantially perpendicular to the silicon surface 12. The direction of upward extension of the vertical portion of the storage electrode pillar 7/high-k dielectric insulator 8 is also perpendicular or substantially perpendicular to the silicon surface 12. Moreover, the direction of upward extension of the counter electrode 9 is also perpendicular or substantially perpendicular to the silicon surface 12. The geometry of a WU cell is: (1) a vertical drain region (2), (2) a vertical gate region (1) (could be a FINFET, triple gate, planar transistor, etc.), (3) a vertical portion with Unique features of the vertical source region (5) connected to the capacitor storage electrode (7) (4), (5) high-k dielectric layer or insulator with vertical portion (8), and (6) vertical counter electrode plate (9). It is configured as shown. A vertical drain portion (2), a vertical gate region (1), a vertical source region (5), a vertical portion of the capacitor storage electrode (7), a vertical portion of the high-k dielectric layer or insulator (8), and a vertical counter electrode plate ( 9) are parallel or substantially parallel.

As a result, the overall size of the WU cell can be compressed due to this unique structural innovation, and the cell size is particularly compressed by the multiple self-alignment techniques used between these vertical structures, resulting in a very small foam. It can be a 1T1C memory cell with a form-factor. Moreover, since the essentially connected regions of this WU cell, such as the drain (2), gate (1), source (5), and counter electrode plate (9), are all raised above the original silicon surface (12), these Necessary interconnections (metal lines, etc.) of the much more compact pitch (line width + space) rule, used to connect contact areas, are flatter. ) can be achieved due to surface topography.

One embodiment of how to make this WU cell is described below (fin structure transistors, e.g. FinFET/triple gate transistors, are assumed to be used in the subsequent process, but other types of transistors, such as planar transistors, etc. can be used similarly).

(a) An oxide-1 layer is grown on a p-type silicon wafer substrate (which may be a p-well such as a triple-well or twin-well structure). Afterwards, a layer of nitride-1 is deposited. Afterwards, a photolithography method is used to define the active area for placing future transistors. Outside of this active region, the silicon material is etched away and a shallow trench isolation whose surface is approximately 25 to 30 nm below the silicon surface is formed using thermally grown oxide-2 regions 20 (or deposited oxide, etc.). It forms trench isolation (STI), and the STI thickness can be 500-2000 nm separately deep into the silicon substrate. Figure 2a shows the result - a gate region 21, an oxide-3 layer 22 below as the gate-dielectric, and a Cap-1 layer 23 (nitride) on top of the gate structure 21. -4 layers 232/oxide-4 layers 231), and a spacer 24 surrounding the gate region 21 (including nitride-5 layers 242/oxide-5 layers 241) - see. The material of the spacer may be a nitride, or an oxide, or a low dielectric constant material (such as k<3), or any combination thereof. The isolation region (e.g. FinFET or STI of planar transistor respectively) is formed according to well-known general processing methods. A photo lithography process and an anisotropic etch process are then used to remove the insulator (including gate dielectric 22) for the drain region, as shown in Figure 2b.

(b) An anisotropic etching method is used to dig out the exposed silicon material within the active region to form a concave-1 region 31, and the depth of this concave-1 region 31 is 25 nm or 30 nm. As a depth, it can be deeper than the surface of STI 20 (about 20 nm deep from the silicon surface). A thick oxide-6 layer 32 is then deposited to fill the concave-1 region 31, with a portion of the oxide-6 layer 32 remaining inside the concave-1 region 31, as shown in FIG. 3A. Uses etch-back technology to ensure that the The top of the remaining oxide-6 layer 32 is lower than the silicon surface 12, and the remaining oxide-6 layer 32 is an isolator region.

(c) Selective Epitaxy Growth (SEG) or Atomic Layer Deposition (ALD) technology is then applied to the oxide-6 layer 32 inside the concave-1 region 31. Exposed on the sidewalls of the concave-1 region 31 as single-crystalline seeds to achieve a layer of silicon containing material 41 (such as silicon, SiC, or SiGe). used for growth from silicon (Figure 4a). This SEG or ALD process can continue with increasing height and some controlled doping concentration within the vertically formed drain region 42, as shown in Figure 4b. This vertical drain region 42 may be named Vertical Tiering Drain (VTD).

(d) An oxide-7 layer 51 is then deposited, after which a flat silicon surface is achieved (referred to as reference surface 52, in contrast to pristine silicon surface 12), as shown in Figure 5A. ) is etch-backed to ensure that Photolithography is then performed to create a pattern of photoresist 53 for subsequent capacitor formation, as shown in FIG. 5B.

(e) FIG. 6A shows that a portion of the oxide-7 layer 51 is then removed within the capacitor region, and a portion of the nitride-5 layer 242 and a portion of the oxide-3 layer 22 are also removed. see. An anisotropic etching method is then used to create another concave-2 region 61 to be used as part of the future formed capacitor, as shown in FIG. 6B.

(f) Further, the photoresist 53 is peeled off and an oxide-8 isolating layer 71 surrounding the side and bottom surfaces of the concave-2 region 61 is formed (this is a thin oxide-8 isolating layer 71). This can be accomplished by thermal growth of the 8-layer 71 or by depositing a high-density oxide-8 layer 71), followed by four sidewalls of oxide-8 overlying it using Spin on Glass (SOG) material. Both bottom surfaces are protected and SOG is removed using different techniques to create concave-2 regions 61 with the oxide-8 isolation layer 71 structure shown in Figure 7.

(g) A thick SOG layer 80 is then deposited and an etch-back technique is used to fill the SOG material 80 into the concave-2 region 61 to the designed height, as depicted in Figure 8. Leave it to be lower than the surface (12). Furthermore, the etch ( method (which may be anisotropic or isotropic) is used. As shown in Figure 9, there is exposed silicon 91 on the upper sidewall of concave-2 region 61.

(h) Then, by using the exposed silicon 91 as a single-crystalline seeding region, a vertical source region parallel to the source edge of the transistor can be grown with some selective doping concentration by SEG or ALD techniques. there is. The grown source region may be a silicon contacting material, such as polysilicon, SiC, or SiGe. This vertical source region 92 is named the Vertical Tiering Source (VTS), which can be just lightly doped, or for more sophisticated needs and designs, this vertical source pillar region 92 can be doped with a variety of may have a doping concentration profile). If necessary, a very short time interval laser annealing method (or fast thermal annealing or other re-crystallization technique) is then used and the SEG (or ALD) source region 92/ It can be applied to the wafer to achieve high material quality in the vertical diffusion area including drain region 42 (FIG. 10). Figure 11 shows that SOG material can be removed from concave-2 region 61. In another example, it is possible to simultaneously form vertical drain region 42 and vertical source region 92 based on a similar process shown in FIGS. 2B, 3A, 4A, and 4B. In this situation, the upper surfaces of the vertical source region and the vertical drain region may be aligned.

(i) An insulating layer is then provided to cover a portion of the VTS source region 92, leaving the upper portion of the VTS source region 92 exposed. This can be achieved with two options.

1. One way to wrap the VTS source pillar 92 and oxide-8 layer 71 is to wrap a thin oxide-9 layer (“covering”) over the VTS source pillar 92 and oxide-8 layer 71. to grow a “covering isolator” (123) (FIG. 12a). In this situation, this thin oxide-9 layer 123 may be a thermal oxide layer growing (or derived from) the VTS source pillar 92 and oxide-8 layer 71. Then, using an anisotropic etching technique, a layer of oxide-9 123 is formed on the top surface of the wrapped VTS source pillar 92 to expose the top silicon region of the VTS source pillar 92, as shown in Figure 13A. Remove part. A metal layer 122 is then deposited so that it has a connection on the top exposed VTS source pillar 92 but is outside of the concave-2 region 61 by the oxide-8 layer 71. It is completely isolated from the silicon substrate (Figure 14a).

2. Alternatively, a nitride-6 layer (“covering isolator”) 121 can be deposited at a well-controlled thickness to surround the VTS source pillar 92 and oxide-8 layer 71 as shown in Figure 12b. . The etch-back method was then used to deposit a nitride-6 layer 121 surrounding the four sidewalls of the concave-2 region 61 along with the exposed upper portion of the VTS source pillar 92, as shown in Figure 13b. leave it behind Furthermore, a metal layer 122 (or another choice of conductive material, such as an n+ doped polysilicon layer or a silicide layer, etc.) can be deposited to connect the metal layer 122 onto the top exposed VTS source pillar 92. However, it is completely isolated from the outer silicon substrate of the concave-2 region 61 by the oxide-8 layer 71 (FIG. 14b). Compared to FIG. 14B, the metal layer in FIG. 14A has almost no zigzags surrounding the top exposed surface of the VTS source pillar 92 and smoothly surrounding the oxide-8 layer 71/oxide-9 layer 123.

(j) Figures 15 to 20 below are based on the structure of Figure 14b. The etch-back technique is used to remove the metal layer 122 on the top of the reference surface 52 and the metal layer 122 on the bottom of the concave-2 region 61, i.e., four pillars on the side walls. This is achieved by collapsing the upper collar-ring, but not connecting these fillers to the bottom (Figure 15). A thick layer of SOG material 124 (or any suitable fill material such as amorphous or polysilicon, etc.) is then deposited and an etch-back process technique is used to have a flat surface on top (FIG. 16).

(k) Depositing an oxide-9 layer (125) and a nitride-7 layer (126). Photolithography techniques are used to pattern the photoresist 127 to create a counter-electrode plate region that cuts perpendicularly into the concave-2 region 61. Because the concave-2 region 61 is deep, the final cutting process will be performed in stages (Figure 17 shows the upper portion of the SOG pillar has been removed). Then, more complete etching continues until the counter electrode plate area 128 is well defined as shown in FIG. 18. This counter electrode formation also collapses the ring structure of both the VTS source pillar 92 and the metal electrode pillar 129, thereby isolating the individual signal storage electrode pillars 129 and forming a high-k dielectric layer between them. It is placed against a counter electrode plate with a dielectric layer.

(l) Remove the SOG layer and form a high-k dielectric insulating layer 130 for the capacitor surrounding the metal electrode pillar 129, and then the already formed central void as the location of the counter electrode plate 131. A metallic material (or other conductive material such as n+ doped polysilicon or amorphous silicon or silicide) is deposited to fill the . The top of the counter electrode plate 131 may be aligned with the top of the high-k dielectric insulating layer 130 and the top of the metal electrode pillar 129, and the additional oxide layer 134 may be aligned with the top of the counter electrode plate 131. It can be located (Figure 19).

(m) Figure 20 shows that the second reference surface 132 has been created. If the surface 133 of the VTD drain region 42 is used as a wide open level reference, then the metal interconnects, such as bit lines 11 connecting the DRAM cells, will have a surface topography of the second This can be achieved much more easily because it is much smoother than previous attempts to drill holes to connect the bit lines 11 on top of the reference surface 132 to the original silicon surface 12. As a result, a smaller metal pitch of the bit lines 11 can be achieved to connect the drain regions 42 of individual cells. The two connections of the additional metal lines to connect the gate 1 and the counter electrode plate 131 suffer from much fewer topography problems than before.

Figure 21A corresponds to Figure 1A, but has additional descriptions of most components of the DRAM cell of Figure 1A. This proposed WU cell includes an asymmetric transistor coupled to a capacitor. The asymmetric transistor includes a drain region 42 (or first conductive region) extending upward from the isolator region 32. It will also be described that drain region 42 extends downward from silicon surface 12 to isolator region 32 and upward from silicon surface 12 to a top surface that may be higher than the top of gate 1. You can. Gate 1 is located above silicon surface 12 and extends upward from gate dielectric 22. The source region 92 (or second conductive region) of the asymmetric transistor extends upward from the first portion 711 of the isolation layer 71. Source region 92 extends downward from silicon surface 12 to first portion 711 of isolation layer 71 and upward from silicon surface 12 to a top surface that may be higher than the top of gate 1. It can also be explained as extending to . Channel region 14 is beneath gate region 1 and contacts source region 92 and drain region 42. Furthermore, the upward extension direction of drain region 42, gate region 1, and source region 92 is perpendicular or substantially perpendicular to silicon surface 12. Moreover, spacer 24 is disposed on top of silicon surface 12 and covers at least two sidewalls of gate region 1, where drain region 42 and source region 92 are in contact with spacer 24. . The silicon surface may be a silicon substrate surface when the transistor is a planar transistor, or it may be the top surface of a fin structure when the transistor is a fin structure transistor, such as a FinFET or triple gate transistor.

Additionally, in an asymmetric transistor, the shape or size of drain region 42 may be different from the shape or size of source region 92. In one embodiment, drain region 42 (or source region 92) includes a lower portion and an upper portion stacked vertically over the lower portion, with the lower portion contacting channel region 14. Furthermore, the doping concentration profile of the drain/source region is controllable, for example, the doping concentration profile from the bottom to the top of the drain/source region can be divided into (1) lightly doped zone, usually doping zone, greater doping zone, and heavily doping zone; or (2) moderate doping zone, low doping zone, large doping zone, and high doping zone; or (3) an un-doped zone, a moderately doped zone, a large doped zone, and a highly doped zone. Here, the concentration of the high-concentration doping zone is larger than the concentration of the large doping zone, the concentration of the large doping zone is larger than the concentration of the normal doping zone, the concentration of the normal doping zone is larger than the concentration of the low-concentration doping zone, and the low-concentration doping zone is The concentration of the zone is greater than that of the undoped zone.

The capacitor is partially formed within the recess 61 and the isolation layer 71 is located within the recess, where the first portion 711 of the isolation layer 71 covers the side wall of the recess 61 and the isolation layer ( The second part 712 of 71 covers the bottom wall of the recess 61. Moreover, the capacitor extends upwardly from the second portion 712 of the isolation layer 711. A capacitor extends downwardly from silicon surface 12 to a second portion 712 of isolation layer 71 and upwardly from silicon surface 12 to a third top surface that may be higher than the top of gate 1. It can also be explained as being. The capacitor includes a capacitor electrode 129 (or first electrode) including a connecting portion 1292 and an upright portion 1291. The connecting portion 1292 contacts the source region 92 and the upright portion 1291 extends upward from the second portion 712 of the isolation layer 71 . The capacitor also includes an insulating layer 130 that includes a third portion 1303 and a fourth portion 1304. The third portion 1303 of the insulating layer 130 extends upward from the second portion 712 of the insulating layer 71 . The fourth portion 1304 of the insulating layer 130 covers the second portion 712 of the insulating layer 71 . The capacitor further includes a counter electrode 131 (or a second electrode) extending upward from the fourth portion 1304 of the insulating layer 130. Here, the upwardly extending direction of the upright portion 1291 of the capacitor electrode 129, the third portion 1303 of the insulating layer 130, and the counter electrode 131 is perpendicular to the silicon surface 12 or substantially It is vertical. Moreover, the upper surfaces of the third portion 1303 of the insulating layer 130, the connecting portion 1292 of the capacitor electrode 129, and the counter electrode 131 are no lower than the upper surface of the gate region 1.

The DRAM cell further includes a covering isolator 123 between the upright portion 1291 of the first electrode 129 and the first portion 711 of the isolation layer 71, the upper surface of the covering isolator 123 having: It is no higher than the top surface of source area 92 to reveal a portion of source area 92. The connecting portion 1292 of the capacitor electrode 129 covers the exposed portion of the source region 92. The position of the upper surface of the covering isolator 123 is adjustable.

In this DRAM cell, the third portion 1303 of the insulating layer 130, the connecting portion 1292 of the capacitor electrode 129, and the upper surfaces of the counter electrode 131 may be aligned. There is a cap structure 23 above the gate region 1, and the upper surface of the cap structure 23 is connected to the third part 1303 of the insulating layer 130 and the connecting part 1292 of the capacitor electrode 129. ), and is aligned with the upper surface of the counter electrode 131.

Figure 21B corresponds to Figure 1B, but has additional descriptions of most components of the DRAM cell of Figure 1B. Moreover, FIG. 21B is almost identical to FIG. 21B except that at least the capacitor includes an insulating layer 130 comprising a third portion 1303, a fourth portion 1304, and a fifth portion 1305. do. The third portion 1303 of the insulating layer 130 extends upward from the second portion 712 of the insulating layer 71 . The fourth portion 1304 of the insulating layer 130 covers the second portion 712 of the insulating layer 71 . The fifth portion 1305 of the insulating layer 130 is in contact with the connecting portion 1292 of the first electrode 129. The capacitor further includes a counter electrode 131 (or a second electrode) extending upward from the fourth portion 1304 of the insulating layer 130. Here, the upwardly extending direction of the upright portion 1291 of the capacitor electrode 129, the third portion 1303 of the isolation layer 130, and the counter electrode 131 is perpendicular to the silicon surface 12 or substantially It is vertical. Moreover, the upper surfaces of the fifth portion 1305 of the insulating layer 130, the connecting portion 1292 of the capacitor electrode 129, and the counter electrode 131 are no lower than the upper surface of the gate region 1.

The covering isolator in FIG. 21b is indicated by number 121 and is between the upright part 1291 of the first electrode 129 and the first part 711 of the isolation layer 71, where the covering isolator 121 The top surface of isolator 121 is lower than the top surface of source region 92 to expose a portion of source region 92. The connection portion 1292 of the capacitor electrode 129 covers the exposed portion of the source region 92 and may also cover the upper surface of the covering isolator 121. In this DRAM cell, it may be that the fifth portion 1305 of the insulating layer 130, the connecting portion 1292 of the capacitor electrode 129, and the upper surfaces of the counter electrode 131 are aligned. There is a cap structure 23 over the gate region 1, the upper surface of the cap structure 23 having a fifth portion 1305 of the insulating layer 130, a connecting portion 1292 of the capacitor electrode 129, and a counter. It is aligned with the top surfaces of electrode 131.

As a result, the overall size of the WU cell can be compressed due to this unique structural innovation, and the cell size is specifically compressed by multiple self-alignment techniques. Together with the above-mentioned examples and descriptions, it is hoped that the features and ideas of the present invention are well explained.

Those skilled in the art will readily appreciate that numerous modifications and variations of the apparatus and methods may be made while retaining the teachings of the present invention. Accordingly, the above disclosure should be construed as limited only by the scope and boundaries of the appended claims.

Claims (35)

As a DRAM cell structure,
transistor;
A concave formed beneath the silicon surface;
an isolation layer located within the recess, wherein the isolation layer includes a first portion covering a first side wall of the recess and extending upward from a bottom wall of the recess, and a second portion covering the bottom surface of the recess. -; and
A capacitor coupled to the transistor, wherein the capacitor extends upward from the second portion of the isolation layer to a predetermined location higher than the silicon surface.
A DRAM cell structure comprising: According to paragraph 1,
The transistor is,
a first conductive region extending upward and downward from the silicon surface;
a gate region over the silicon surface and extending upward from the gate dielectric layer;
a second conductive region extending upward and downward from the silicon surface; and
a channel region below the gate region and in contact with the first conductive region and the second conductive region;
and wherein an upward extension direction of the first conductive region, the gate region, and the second conductive region is perpendicular or substantially perpendicular to the silicon surface. According to paragraph 2,
The capacitor is,
a first electrode including a connecting portion in contact with the second conductive region and an upright portion extending upwardly from the second portion of the isolation layer;
an insulating layer comprising a third portion extending upwardly from the second portion of the insulating layer and a fourth portion covering the second portion of the insulating layer; and
a second electrode extending upward from the fourth portion of the insulating layer;
wherein the insulating layer is positioned between the first electrode and the second electrode, and the upright portion of the first electrode, the third portion of the insulating layer, and the upward extending direction of the second electrode are A DRAM cell structure that is perpendicular or substantially perpendicular to the silicon surface. According to paragraph 3,
further comprising a covering isolator between the upright portion of the first electrode and the first portion of the isolation layer, wherein the covering isolator covers the first portion of the second conductive region and the first portion of the isolation layer. wherein the connecting portion of the electrode covers a second portion of the second conductive region. According to paragraph 3,
The insulating layer further includes a fifth portion in contact with the connecting portion of the first electrode, wherein the fifth portion of the insulating layer, the connecting portion of the first electrode, and the upper surface of the second electrode DRAM cell structures, where they are no lower than the top surface of the gate region. According to clause 5,
The fifth portion of the insulating layer, the connecting portion of the first electrode, and the upper surfaces of the second electrode are aligned. According to paragraph 2,
A DRAM cell structure, wherein the top surfaces of the first conductive region and the second conductive region are no lower or lower than the top surface of the gate region. In clause 7,
The top surfaces of the first conductive region and the second conductive region are aligned. According to paragraph 2,
wherein the top surface of the first conductive region is higher than the silicon surface, and the first conductive region extends downward from the silicon surface to the first isolator region. According to clause 9,
wherein the first conductive region includes a lower portion and an upper portion vertically stacked on the lower portion, the lower portion contacting the channel region and the first isolator region. According to paragraph 2,
wherein the top surface of the second conductive region is higher than the silicon surface, and the second conductive region extends upward from the first portion of the isolation layer to the top surface of the second conductive region. According to clause 11,
wherein the second conductive region includes a lower portion and an upper portion vertically stacked on top of the lower portion, the lower portion contacting the channel region and the first portion of the isolation layer. According to paragraph 2,
A DRAM cell structure, wherein the shape or size of the first conductive region is different from the shape or size of the second conductive region. According to paragraph 2,
A DRAM cell structure further comprising a spacer overlying the silicon surface and covering at least two sidewalls of the gate region, wherein the first conductive region and the second conductive region are in contact with the spacer. According to paragraph 2,
The DRAM cell structure further comprising a covering isolator derived from the lower portion of the second conductive region and from the first portion of the isolation layer. According to clause 15,
wherein the covering isolator comprises an oxide material, the isolation layer comprises an oxide material, and the second conductive region comprises a silicon material. A method of manufacturing a DRAM cell, comprising:
forming a first gate structure and a second gate structure positioned over the silicon surface;
forming a first spacer covering a sidewall of the first gate structure and a second spacer covering a sidewall of the second gate structure, wherein the first spacer and the second spacer are positioned above the silicon surface; and
forming a concave between the first spacer and the second spacer to expose a silicon edge beneath the silicon surface; and
forming a first conductive region based on the exposed silicon edge by selective epitaxial growth.
A manufacturing method comprising: According to clause 17,
Prior to forming the first conductive region, the method further includes forming an isolator region within the recess, wherein an upper surface of the isolator region is lower than the silicon surface. According to clause 18,
The first conductive region extends upward from the isolator region and contacts the first spacer and the second spacer. According to clause 17,
forming another recess beneath the silicon surface;
forming an isolation layer located within the other recess, wherein the isolation layer includes a first portion covering a first side wall of the other recess and a second portion covering a bottom surface of the other recess; and
Forming a capacitor, wherein the capacitor extends upward from the second portion of the isolation layer to a predetermined location higher than the silicon surface.
A manufacturing method further comprising: A method of manufacturing a DRAM cell having a transistor, comprising:
forming a concave under the silicon surface;
forming an isolation layer located within the recess, wherein the isolation layer includes a first portion covering a first side wall of the recess and a second portion covering a bottom surface of the recess; and
partially forming a capacitor within the recess, wherein the capacitor comprises:
a first electrode including a connecting portion in contact with the transistor and an upright portion extending upward from the second portion of the isolation layer;
an insulating layer comprising a third portion extending upwardly from the second portion of the insulating layer and a fourth portion covering the second portion of the insulating layer; and
a second electrode extending upwardly from the fourth portion of the insulating layer
Including, manufacturing method. According to clause 21,
Before forming the concave portion below the silicon surface,
forming another depression beneath the silicon surface;
forming a first isolator region within the other recess, wherein the upper surface of the first isolator region is lower than the silicon surface; and
forming a first conductive region on the first isolator region, wherein the first conductive region extends upward from the first isolator region to a predetermined region higher than the silicon surface.
A manufacturing method further comprising: According to clause 21,
Before forming the capacitor,
further comprising forming a second conductive region on the first portion of the isolation layer, wherein an upper surface of the first portion of the isolation layer is lower than the silicon surface, and the second conductive region is located on the first portion of the isolation layer. and extending upward from the first portion of the isolation layer to a predetermined area higher than the silicon surface. As a DRAM cell structure,
a first concave portion and a second concave portion formed below the silicon surface;
an isolation layer located within the second recess, wherein the isolation layer includes a first portion covering a first side wall of the second recess and a second portion covering a bottom surface of the second recess;
a capacitor formed partially within the second recess and extending upwardly from the second portion of the isolation layer; and
A transistor comprising:
a drain region extending upward from the isolator region located within the first recess;
a gate region overlying the silicon surface and extending upward from a gate dielectric layer;
a source region formed partially within the second recess and extending upwardly from the first portion of the isolation layer; and
a channel region beneath the gate region and in contact with the drain region and the source conductive region;
A DRAM cell structure wherein the drain region, the source region, and the top surface of the capacitor are higher than the silicon surface. According to clause 24,
A DRAM cell structure, wherein the drain region, the source region, and the top surfaces of the capacitor are higher than the top surface of the gate region. According to clause 24,
The top surfaces of the isolator region and the first portion of the isolation layer are lower than the silicon surface. According to clause 24,
A DRAM cell structure, wherein a second transistor adjacent to the DRAM cell shares the drain region with the transistor of the DRAM cell. According to clause 24,
The capacitor is,
a first electrode including a connecting portion in contact with the source region and an upright portion extending upward from the second portion of the isolation layer;
an insulation comprising a third portion extending upwardly from the second portion of the isolation layer, a fourth portion covering the second portion of the isolation layer, and a fifth portion contacting the connecting portion of the first electrode. floor; and
comprising a second electrode extending upwardly from the fourth portion of the insulating layer;
wherein the fifth portion of the insulating layer, the connecting portion of the first electrode, and the top surfaces of the second electrode are no lower than the top surface of the gate structure. According to clause 28,
further comprising a cap structure over the gate region, wherein the top surface of the cap structure includes the fifth portion of the insulating layer, the connecting portion of the first electrode, and the top surfaces of the second electrode. Aligned, DRAM cell structure. According to clause 28,
A DRAM cell structure, wherein a second DRAM cell adjacent to the DRAM cell includes a second capacitor sharing the second electrode with the capacitor of the DRAM cell. As a DRAM cell structure,
a first concave portion and a second concave portion formed below the silicon surface;
an isolation layer located within the second recess;
a capacitor partially formed within the second recess; and
A transistor comprising:
a drain region partially formed within the first recess;
a gate region above the silicon surface and extending upward from a gate dielectric layer; and
comprising a source region partially formed within the second recess;
A DRAM cell structure wherein the drain region, the source region, and the top surfaces of the capacitor are higher than the silicon surface. According to clause 31,
A DRAM cell structure, wherein a second transistor adjacent to the DRAM cell shares a drain region with a transistor of the DRAM cell. According to clause 31,
The capacitor is,
a first electrode including a connecting portion in contact with the source region and an upright portion extending upward from the isolation layer;
insulating layer; and
comprising a second electrode extending upward from the insulating layer;
wherein a second DRAM cell adjacent to the DRAM cell includes a second capacitor sharing the second electrode with the capacitor of the DRAM cell. According to clause 31,
A DRAM cell structure, wherein the drain region or the source region comprises a silicon containing material. According to clause 31,
and a spacer overlying the silicon surface and covering at least two sidewalls of the gate region, wherein the spacer comprises a nitride layer, an oxide layer, a low dielectric constant material, or any combination thereof. Including, DRAM cell structure.