Abstract:
A new method is provided for the creation of the bit line contact plug. CUB capacitors typically are located adjacent to the bit line contact plug, a parasitic capacitance therefore exists between the CUB and the contact plug. Typical interface between the CUB and the bit line contact plug consists of a dielectric. By creating an air gap that partially replaces the dielectric between the CUB and the bit line contact plug, the dielectric constant of the interface between the bit line and the CUB is reduced, thereby reducing the parasitic coupling between the bit line contact plug and the CUB. This enables the creation of CUB capacitors of increased height, making the CUB and the therewith created DRAM devices better suited for the era of sub-micron device dimensions.

Description:
BACKGROUND OF THE INVENTION 
     (1) Field of the Invention 
     The invention relates to the fabrication of integrated circuit devices, and more particularly, to a method to fabricate Capacitors Under the Bit line (CUB) of DRAM devices. The bit line contacts are provided with a surrounding air gap, reducing the parasitic capacitance between the bit line and the capacitor that is created under the bit line. 
     (2) Description of the Prior Art 
     Developments in the semiconductor industry have over the years been aimed at creating higher performance devices at competitive or lower prices. These developments have resulted in extreme miniaturization of semiconductor devices, which has been made possible by numerous and mutually supporting advances in semiconductor processes and by advances in the materials that are used for the creation of semiconductor devices, this in combination with new and sophisticated device designs. While most semiconductor devices are aimed at processing digital data, Dynamic Random Access Storage (DRAM) devices incorporate data retention or storage capabilities in the design of the semiconductor device. The creation of capacitive components, which are the basis for the data storage capabilities of DRAM devices, must emphasize that these capacitive components are created on a relatively small surface area of a semiconductor substrate while using methods and procedures that are well known in the art of creating semiconductor devices. 
     It is well known that capacitors can be created between layers of polysilicon, poly to polycide or metal or between layers of metal. Capacitors can be either of a planar design, for reasons of process simplicity, or can be three-dimensional, resulting in a smaller footprint as commonly used in DRAM devices. 
     Dynamic Random Access Memory (DRAM) devices typically consist of arrays of memory cells that perform two basic functions, that is the field effect transistor that serves as a charge transfer transistor and a capacitor. The field effect transistor (a source region, a drain region and a gate electrode) serves the function of providing access to the capacitor, the capacitor serves the function of data retention or storage. Binary data is stored as an electrical charge on the capacitor in the individual DRAM memory cells. Contacts to the surrounding circuits are provided for the DRAM memory cell. DRAM memory is so named because DRAM cells can retain information only for a limited period of time before they must be read and refreshed at periodic intervals. In a typical DRAM construction, one side of the transistor is connected to one side of the capacitor. The other side of the transistor and the transistor gate electrode are connected to external connect points that form the bit and word lines. The other side of the capacitor is connected to a reference voltage. 
     In creating storage capacity in semiconductor memory devices, it is essential that storage node capacitor cell plates are large enough so that an adequate voltage can be retained on the capacitor plates. This even in the presence of parasitic capacitances and circuit noise that may be occur in the circuit during circuit operation. With the continuing increase in circuit density, this latter requirement becomes even more of a challenge in maintaining required storage capabilities. Future generations of dynamic memory storage devices are expected to continue to evolve along the path of further miniaturization and will therefore continue to pose a challenge in creating capacitive storage capabilities at decreasing device dimensions. As the DRAM technology continuous to be scaled down, the height of the storage capacitor needs to be increased further in order to maintain large enough capacitive storage capability for each memory cell. This poses a challenge of reducing parasitic capacitive effects that, with the increase in the height of the storage capacitor, tend to have an increasingly negative effect on the DRAM cell storage capability. The invention addresses this concern and provides a method whereby the effect of parasitic capacitance is reduced for capacitors of increased height by introducing an air-gap as part of the structure. 
     U.S. Pat. No. 6,168,989B1 (Chiang et al.) shows a crown COB capacitor. 
     U.S. Pat. No. 6,110,775 (Fujii et al.), U.S. Pat. No. 6,165,839 (Lee et al.), U.S. Pat. No. 6,074,908 (Huang) disclose related capacitor patents. 
     U.S. Pat. No. 6,140,200 (Eldridge) shows voids and capacitor processes. 
     SUMMARY OF THE INVENTION 
     A principle objective of the invention is to create a capacitor-under-bit-line (CUB) whereby parasitic capacitance between the bit line contact and the CUB is significantly reduced. 
     Another objective of the invention is to create a capacitor-under-bit-line (CUB) that results in a significant reduction of the signal-to-noise ratio during the sensing operation of the DRAM cell. 
     Yet another objective of the invention is to provide a method of creating CUB DRAM devices that have been provided with an oxide ring surrounding polysilicon plugs. 
     In accordance with the objectives of the invention a new method is provided for the creation of the bit line contact plug. CUB capacitors typically are located adjacent to the bit line contact plug, a parasitic capacitance therefore exists between the CUB and the contact plug. The interface between the CUB and the bit line contact plug typically consists of a dielectric. By creating an air gap that partially replaces the dielectric between the CUB and the bit line contact plug, the dielectric constant of the interface between the bit line and the CUB is reduced, thereby reducing the parasitic coupling between the bit line contact plug and the CUB. This enables the creation of CUB capacitors of increased height, making the CUB and the therewith created DRAM devices better suited for the era of sub-micron device dimensions. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 shows a cross section of a conventional DRAM cell. 
     FIG. 2 shows a cross section of a conventional, simplified DRAM cell with CUB capacitors. 
     FIGS. 3 through 15 address the invention, as follows: 
     FIG. 3 shows a cross section of a semiconductor substrate on the surface of which gate electrodes have been created, a first layer of dielectric has been deposited over which a layer of etch stop material has been deposited. 
     FIG. 4 shows a cross section after openings have been created in the layer of dielectric for a bit line contact plug and for two CUB capacitors. The openings have been filled with polysilicon, providing conductive plugs through the first layer of dielectric. 
     FIG. 5 shows a cross section after a second layer of dielectric has been deposited, a patterned first layer of photoresist has been created on the surface of the second layer of dielectric. The openings that have been created in the layer of photoresist align with the underlying contact plugs for the CUB capacitors that have been created in the first layer of dielectric. 
     FIG. 6 shows a cross section after the second layer of dielectric has been etched in accordance with the openings that have been created in the first layer of photoresist. The first electrode, dielectric and second electrode of the CUB capacitors have been deposited inside the openings created in the second layer of dielectric. The patterned layer of photoresist has been removed. 
     FIG. 7 shows a cross section after a second patterned layer of photoresist has been created on the surface of the layer that serves as the second electrode of the CUB capacitors. The opening created in the patterned second layer of photoresist aligns with the contact plug of the bit line that has been created in the first layer of dielectric. 
     FIG. 8 shows a cross section after an opening has been created in the second layer of dielectric in accordance with the opening that has been created in the second layer of photoresist. The patterned second layer of photoresist has been removed, a layer of F-poly has been deposited over the surface of the second electrode of the CUB capacitors and the inside surfaces of the opening created in the second layer of dielectric. 
     FIG. 9 shows a cross section after the F-poly has been removed from the surface of the second electrode of the CUB capacitors, a layer of LPTEOS has been deposited. 
     FIG. 10 shows a cross section after the LPTEOS has been removed from the surface of the second electrode of the CUB capacitors, a layer of D-poly has been deposited. 
     FIG. 11 shows a cross section after the D-poly has been removed from the surface of the second electrode of the CUB capacitors, exposing the surface of the concentric rings of material that have been deposited inside the opening that has been created in the second layer of dielectric that aligns with the bit line contact plug created in the first layer of dielectric. 
     FIG. 12 shows a cross section after the layer of LPTEOS has been removed from the opening that has been created in the second layer of dielectric that aligns with the bit line contact plug created in the first layer of dielectric. 
     FIG. 13 shows a cross section after a layer of PETEOS has been deposited over the surface of the second electrode of the CUB capacitors, including the surface of the opening that has been created in the second layer of dielectric that aligns with the bit line contact plug in the first layer of dielectric. 
     FIG. 14 shows a top view of the CUB of the invention, including the bit line contact and the layers of material that surround the bit line contact plug. 
     FIG. 15 shows a cross section of the completed DRAM cell of the invention, including the CUB capacitors and the bit line contact. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     The main concerns that arise during the fabrication of sub-micron DRAM memory cells and that is addressed by the invention will be highlighted first. 
     During read/sensing operation of a typical DRAM cell, the signal charge that has been stored in the cell capacitor will be transferred to the bit line of the DRAM cell. This results in a small voltage differential or signal DV between a pair of bit lines that are connected to a latch-type sense amplifier. The magnitude of the signal DV is related to C s /(C b +C s ), where C b  is the total bit-line capacitance and C s  is the cell capacitance (FIG.  2 ). Therefore, the C b  should be as small as possible so that the signal is large enough for sensing. However, in the conventional CUB (capacitor under bit line) scheme, the C b  is typically larger than in the corresponding COB (capacitor over bit line) scheme, as contributed by the capacitance from the long bit-line contact to the capacitor sidewalls (FIG.  2 ). 
     As DRAM technology continuous to be scaled down, the height of the storage capacitor needs to be increased accordingly in order to maintain large enough capacitance storage capability for each cell. However, the C b , including all other parasitic capacitances between the bit lines and the storage nodes, increases as a result of the scaling down of the DRAM device. To take advantage of the CUB scheme for fabricating DRAM devices, the value of C b  must be decreased to the maximum extent possible. The invention addresses this aspect of DRAM design and provides a method of using air-gaps as part of the DRAM design. 
     A new fabrication method is provided for the creation of CUB DRAM cells with the creation of an “air gap” surrounding each bit line contact. The air gap assures that the bit line capacitance is significantly reduced due to the low dielectric constant of air, which equals approximately 1. The signal to noise ratio during sensing is therefore significantly improved. 
     The essential aspects that are addressed in order to create the indicated air gap include: 
     the forming of oxide rings around bit line poly plugs, the poly plugs have a width between 0.1 and 0.15 μm 
     immersing the dip oxide rings in HF to form air-gaps after the formation of the polysilicon bit-line plugs has been completed, and 
     using PETEOS as ILD above the air gaps, which adequately seals the air-gap due to the poor step coverage or “overhang” that is typical of deposited layers of PETEOS. 
     The approach of storing charges vertically in a trench results in stacking the storage capacitor on top of the access transistor. The lower electrode of the stacked capacitor (STC) is in contact with the drain of the access transistor whereby the bit line runs over the top of the stacked capacitor. For STC cells to be made feasible for a larger capacity DRAM, an insulator with a larger dielectric constant than that of SiO 2  must be used. 
     It has previously been stated that one of the design objectives in designing dynamic DRAM devices is the design of a capacitor that provides maximum electrical charge storage capability in one individual DRAM cell. An individual Dynamic Random Access Memory (DRAM) cell typically consists of a single metal-oxide-semiconductor field-effect-transistor (MOS-FET) that is provided with a single capacitor for storing electrical data. A unit or bit of data is stored on the capacitor of the DRAM cell as an electrical charge. A number of different approaches have over the years been explored to provide adequate or optimum storage capability. One of these approaches creates stacked capacitors having a three dimensional structure. Such stacking of the capacitors can take the form of double stacking, fin structured stacking, cylindrical designs, spread stacking and boxed structured stacked capacitors. 
     A Prior Art method of creating a DRAM memory cell is next highlighted using FIG.  1 . Shown in FIG. 1 is a lightly doped p-type single crystal silicon substrate  10  with a crystallographic orientation of &lt;100&gt;. The highlighted DRAM memory region is electrically isolated from its peripheral regions by Field Oxide (FOX) regions  34  that surround the memory region. The FOX region is typically formed by creating Shallow Trench Isolation regions in the surface of the substrate  10 . This process starts by etching trenches in the surface of the substrate that are typically between 2000 and 4000 Angstrom deep. The trenches are lined with a layer of thin thermal oxide and filled with an insulating material such as silicon dioxide. The surface of the trenches is then polished (using CMP technology) and made equal in elevation with the surface of the surrounding silicon. A thin layer of gate oxide  12  (between about 40 and 90 Angstrom thick) is next grown over the device area of the surface of the substrate  10  to serve as stress relieve layer. The gate structure of the transistors  14  contains the typical gate structure elements of source ( 16 ) and drain ( 18 ) regions (formed by implanting an n-type dopant into these regions), the gate electrodes  20  that contain a (n +  doped) polysilicon layer  22  and a silicide layer  24  (to make electrical contact with the top of the gate electrode) and gate spacers  26 . The doping of layer  22  can use arsenic or phosphorous as a dopant, typically with a concentration of between 1.0E20 and 1.0E21 atoms/cm and an energy between about 30 and 70 KeV. The polysilicon layer is typically between about 500 and 1500 Angstrom thick and is deposited using Low Pressure Chemical Vapor Deposition (LPCVD) technology. A refractory metal silicide layer (not shown), preferably of tungsten silicide (WSi 2 ) or tungsten hexafluoride (WF 6 ), can be deposited on the layer of poly using LPCVD to a thickness of between about 500 and 2500 Angstrom. A cap oxide layer (not shown) can be deposited on top of the refractory metal silicide; this layer typically contains SiO 2  and has a top layer of SiN 4  with a thickness of between about 1000 and 2500 Angstrom. The poly layer and the overlying layers are patterned using conventional photolithographic techniques and anisotropic etching to form the poly gate structures over the active area of the silicon substrate while forming word lines over the FOX regions  34 . 
     The insulating sidewall spacers  26  are typically formed by depositing a layer of Si 3 N 4  using LPCVD and anisotropically etching the layer of Si 3 N 4 . The layer of Si 3 N 4  is deposited to a thickness of between about 200 and 800 Angstrom. 
     The source/drain regions  16 / 18  are formed by ion implant using an n-type dopant such as p 31  whereby the process of doping is self-aligned with the formed gate structure. The contacts  16 / 18  are typically doped to a final dopant concentration of between about 1.0E19 and 1.0E21 atoms/cm 2 . 
     The contact regions  28  are provided to establish contact between the source regions  16  and capacitors  30 , contact region  32  provides access to the drain region  18 . Contact  32  forms the bit line contact also referred to as the bit-line self aligned contact. Contact regions  28  form the storage capacitor contacts also referred to as the storage node self aligned contacts  29 . Capacitor contact regions  28  and bit line contact region  32  are typically filled with doped polysilicon to form the capacitor contacts  29  and the bit line  28 ″ contact respectively. Field isolation regions  34  isolate the active transistors  14  from the surrounding areas of the silicon substrate. Regions  36  form isolation regions that can for instance contain boro-phosphosilicate-glass (BPSG) or any other suitable isolation material. 
     Further highlighting the formation of a typical DRAM structure, a relatively thin layer (not shown) of Si 3 N 4  can be deposited over the created gate electrode structures and the exposed surface of the substrate using LPCVD and a gas mixture such as dichlorosilane (SiCl 2 H 2 ) and ammonia (NH 3 ). This layer can be deposited to a thickness of between 50 and 500 Angstrom. After this, a relatively thick insulating layer  36 , typically of borophosphodsilicate (BPSG), can be deposited using LPCVD with tetraethosiloxane (TEOS) as a reactant gas. Boron and phosphorous are added during the deposition of the BPSG layer. Layer  36  is then chemically/mechanically polished to provide a planarized surface where layer  36  has a thickness of between 4500 and 9000 Angstrom over the surface of the gate electrodes. 
     The insulating layer  36  must now be etched to create openings for the contact plugs to form the bit-line and storage node self-aligned contacts. A layer of photoresist is therefore deposited over the surface of layer  36 , this layer of photoresist is masked to the pattern of the contact plugs and anisotropically etched to etch the self-aligned openings for contact plugs  29  and  28 ″. For the etch of the photoresist, plasma etching is preferred using Reactive Ion Etching (RIE) with as etchant a gas mixture containing perfluoroisobutylene (C 4 F 8 ), trofluoromethane (CHF 3 ), methyflouroride (CH 3 F), carbon tetrafluoride (CF 4 ), carbon monoxide (CO), oxygen (O 2 ) and argon (Ar). This etch results in forming the pattern  32  for the self-aligned bit-line contact and the pattern  28  for the self-aligned storage node contact. 
     FIG. 2 shows a somewhat simplified cross section of DRAM cells, a number of the elements that are part of the DRAM cells shown in FIG. 2 have not further been highlighted since these elements have been discussed in detail using FIG.  1 . What has been highlighted in FIG. 2 are the parameters that are of importance to the invention, that is the parameters that affect the voltage difference that can be provided by the capacitive charge of the DRAM cells to the sense amplifier. The relationship that expresses the voltage difference that can be derived from the capacitance storage of the DRAM cell that is shown in cross section in FIG. 2 is as follows: 
     
       
         δV={(V dd /2)*C s }/(C b +C s ) 
       
     
     where: 
     δV is the voltage difference that is provided by the capacitive charge of the Capacitor Under Bit line of the DRAM cell that is shown in cross section in FIG. 2 
     C s  is the cell capacitance 
     C b  is the total parasitic bit line capacitance 
     Shown as parameters in FIG. 2 are: 
     ε, the dielectric constant of the dielectric that separates the bit line from the capacitor  30   
     h, the height of the CUB  30   
     d, the distance between the bit line  28  and the CUB  30 . 
     Advance semiconductor technology requirements of device miniaturization and the like, which have previously been highlighted, typically result in: 
     decreasing the distance d between the bit line  28  and the CUB  30 , and 
     increasing the height h of the capacitor. 
     These changes in the indicated parameters result in, as is also evident from the equation that is shown above: 
     an increase in C b , the total parasitic bit line capacitance, from which follows 
     a decrease in δV, the voltage difference that is provided by the capacitive charge of the Capacitor Under Bit line of the DRAM cell. 
     This latter decrease in δV is to be avoided, the invention provides a method to achieve the avoidance of a decrease in δV. 
     Further shown in cross section of FIG. 2 are the following elements which have not previously been shown in FIG.  1 : 
       21 , the first or bottom electrodes of CUB capacitors  30   
       23 , the dielectric of CUB capacitors  30   
       25 , the second or top electrodes of CUB capacitors  30   
       27 , gate electrodes that have been formed on the surface of substrate  10 ; the gate electrodes  27  that are formed on the surface of regions  34  of field isolation oxide are connected to surrounding devices; the gate electrodes  27  that are created on the active surface region of substrate  10  that is bounded by regions  34  are the gate electrodes of the DRAM cell under discussion; it is clear that the gate structures that have been created over the active surface region of the substrate can be created over an underlying layer of insulation, such as the previously highlighted layer of pad oxide (layer  12 , FIG. 1) 
       38 , an etch stop layer that has been deposited over the surface of layer  36  of dielectric; this etch stop layer  38  is used for the creation of the openings that are required to create CUB capacitors  30  and the bit line extended contact plug  28 ′ 
       40 , a layer of dielectric that surrounds the bit line  28 ′ and the two CUB capacitors  30   
       28 ′, an extension of bit line  28 ″ 
       42 , patterned layers of metal that contact the second electrode  25  of CUB capacitors  30 ; these patterned layers of metal  42  are used to further interconnect CUB capacitors  30   
       44 , a layer of dielectric overlying the patterned layers of metal  42 , and 
       46 , the metallic interconnect to bit line  28 ″ which is used for further interconnection of the bit line to surrounding circuitry such as the sense amplifier. 
     The invention will now be described in detail using FIGS. 3 through 15 for this purpose. 
     FIG. 3 shows a cross section of a semiconductor substrate  10  that has been provided with: 
     STI regions  34   
       19 , word line of FET devices for the DRAM cell under discussion 
       37 , a layer of dielectric, preferably comprising silicon oxide, deposited over the surface of substrate  10 , including the surface of gate electrodes  19  provided on the surface of the substrate  10 , and 
       38 , an etch stop layer, preferably comprising silicon nitride, deposited over the surface of layer  37  of dielectric. 
     As dielectric material for layer  37  can be used any of the typically applied dielectrics such as silicon dioxide (doped or undoped), silicon oxynitride, parylene or polyimide, spin-on-glass, plasma oxide or LPCVD oxide. The material that is used for the deposition of layer  37  of Intra Level Dielectric (ILD) of the invention is not limited to the materials indicated above but can include any of the commonly used dielectrics in the art. The preferred material of the invention for layer  37  is silicon oxide. A typical application of a layer  37  of Intra level Dielectric is depositing a layer of SiO 2  using CVD technology at a temperature of between about 400 and 800 degrees C. The layer  37  of ILD is deposited to a thickness that is adequate to cover and to extend above the top surface of the word line FET devices  19 . The layer  37  is, after it has been deposited, polished using Chemical Mechanical Polishing (CMP) technology. 
     The layer  38  of silicon nitride (Si 3 Ni 4 ) can be deposited using LPCVD or PECVD procedures at a pressure between about 200 mTorr and 400 mTorr, at a temperature between about 600 and 800 degrees C., to a thickness of about 300 to 500 Angstrom using NH 3  and SiH 4  or SiCl 2 H 2 . The silicon nitride layer  38  can also be deposited using LPCVD or PECVD procedures using a reactant gas mixture such as dichlorosilane (SiCl 2 H 2 ) as a silicon source material and ammonia (NH 3 ) as a nitrogen source, at a temperature between about 600 and 800 degrees C., at a pressure between about 300 mTorr and 400 mTorr, to a thickness between about 300 and 500 Angstrom. 
     FIG. 4 shows a cross section of the surface of substrate  10  after: 
     openings  31 ,  33  and  35  have been created in the layers  38  of silicon nitride and  37  of silicon oxide 
     a layer (not shown in FIG. 4) of doped polysilicon has been deposited over the surface of the layer  38  of silicon nitride 
     the surface of the deposited layer of polysilicon has been polished, using methods of Chemical Mechanical Polishing (CMP) down to the surface of the layer  38  of silicon nitride. 
     The sequence of processing steps that are represented by the cross section that is shown in FIG. 4 has resulted in creating conductive plugs  39 ,  41  and  43  through the layer  37  of silicon oxide. The conductive plugs  39 ,  41  and  43  align with bit line (plug  41 ) and capacitor (plugs  39  and  43 ) contact points; the latter contact points are also referred to as storage node contact holes. 
     The patterning and etching of layers  38  and  37  uses conventional methods of photolithography and patterning and etching. The stop layer  38  of silicon nitride can be etched using a SiON or SiN removal process with etchant gasses CH 3 F/Ar/O 2  at a temperature between about 10 and 20 degrees C., a pressure of between about 50 and 60 mTorr with an etch time of between about 40 and 60 seconds. The silicon nitride layer  38  can also be etched using anisotropic RIE using CHF 3  or SF 6 —O 2  or SF 6 /HB 8  as an etchant. 
     Openings  31 ,  33  and  35  in layer  37  of silicon oxide can be formed via anisotropic RIE of the silicon oxide layer  37 , using CHF 3  or CF 4 —O 2 —He as an etchant. 
     The layer of doped polysilicon (not shown in FIG. 4) can be deposited using low-pressure vapor deposition (LPCVD). The thickness of the doped polysilicon layer is between about 3,000 and 4,500 Angstrom such that openings  31 ,  33  and  35  are filled with polysilicon. The layer of doped polysilicon is preferably deposited by LPCVD using a reactant gas mixture of SiH 4  and phosphine (PH 3 ), typically in a temperature range of between 500 and 650 degrees C. 
     The invention continues with the processing steps of, see FIG.  5 : 
     depositing a second layer of silicon oxide over the surface of layer  38  of silicon nitride and the surface of the doped polysilicon plugs  39 ,  41  and  43   
     depositing a first layer  52  of photoresist over the surface of the second layer  50  of silicon oxide 
     patterning and developing the first layer  52  of photoresist, creating openings  51  and  53  in the layer  52  of photoresist that align with the node contacts  39  and  43 . 
     The processing steps that are represented by the cross section that is shown in FIG. 5 have either previously been highlighted and/or follow conventional methods of oxide deposition and photoresist processing. These steps will therefore not be further discussed at this time. 
     Referring to the cross section that is shown in FIG. 6, the following processing steps are highlighted: 
     the layer  50  of silicon oxide has been etched in accordance with the openings  51  and  53  that have been created in the layer  52  (FIG. 5) of photoresist 
     the layer  52  of photoresist is removed from the surface of the etched layer  50  of silicon oxide 
     a layer  54  of HSG has been grown on the surface of oxide layer  50 , including inside surfaces of openings  55  and  57  that have been created in the layer  50  of silicon oxide; this layer  54  of HSG forms the first or bottom electrode of the CUB capacitor 
     the layer  54  of HSG overlying the layer  50  is polished, using methods of CMP, removing the HSG from the surface of layer  50  and leaving the grown layer  54  in place overlying the inside surfaces of openings  55  and  57 ; the lower electrode of the CUB capacitor is now complete 
     a layer  56  of ONO or NO dielectric is deposited over the surface of the oxide layer  50  and the HSG layer  54  to form the dielectric of the capacitor, and 
     a layer  58  of polysilicon is deposited, this layer  58  is used to form the second electrode of the capacitor. 
     Relating to the layer  54  of HSG the following comments apply. Thin films of amorphous and polycrystalline silicon are widely used in semiconductor manufacturing. For example, amorphous silicon can be used for the formation at the gate of CMOS structures for application in the dual gate process since the amorphous silicon can effectively reduce the Boron (B) penetration from the gate to the device region. Doped polycrystalline silicon can be used to form interconnects, gate electrodes, emitter structures and resistors. These silicon thin films are typically formed by LPCVD (low pressure chemical vapor deposition) by decomposition of a silicon gas such as silane (SiH 4 ) or disilane (Si 2 H 6 ). Doping can also be accomplished in the gas phase by introducing a dopant gas such as diborane (B 2 H 6 ), arsine (AsH 3 ) or phosphine (PH 3 ). The deposition temperature during LPCVD is typically from 500 degrees C. to 675 degrees C. and the pressure is typically from 200 mTorr to 2 Torr. The crystalline structure of the ‘as deposited’ film is largely a function of the deposition temperature. At temperatures below about 550 degrees C. the ‘as deposited’ films have an amorphous structure. At temperatures between about 550 degrees C. and 580 degrees C., there is a transition between amorphous silicon and polycrystalline silicon. Hemispherical grain (HSG) polysilicon is typically grown in this transitional range. At temperatures above about 580 degrees C. the ‘as deposited’ films have a polycrystalline structure. 
     For the deposition of layer  56  of ONO, that is a layer of oxide-nitride-oxide, the first layer of oxide is native oxide or thermally grown oxide or CVD deposited oxide. The nitride is deposited by LPCVD at a temperature within the range of 600 to 700 degrees C. to a thickness within the range of between 40 and 60 Angstrom, the final oxidation layer is grown in a furnace at a temperature within the range between 700 and 800 degrees C. for a time period within the range between 30 and 120 minutes. 
     Layer  58 , FIG. 6, forms the top capacitor plate and is to be doped in order to establish the desired level of conductivity. For purposes of post-CMP processing or for RIE processing, layer  58  should be thick enough, such as between for instance about 1,000 and 2,000 Angstrom. Layer  56 , FIG. 6, is a thin layer of dielectric, such as ONO/ON, which isolates the two layers  54  and  58  from each other. 
     FIG. 7 shows in cross section the following processing steps of the invention: 
     a second layer  60  of photoresist is deposited over the surface of the layer  58  of polysilicon 
     the second layer  60  of photoresist is patterned and developed using conventional methods of photolithography and resist development, creating an opening  59  in the second layer  60  of photoresist that aligns with the bit line contact plug  41 . 
     The processing steps that are represented by FIG. 7 use conventional processing and therefore do not need to be further discussed at this time. 
     The cross section that is shown in FIG. 8 represents the following processing steps: 
     layer  58  of polysilicon has been etched in accordance with the openings  59  that has been created in the overlying second layer  58  of photoresist (FIG.  7 ), opening the second or top electrodes  58  for CUB capacitors 
     the etch of layer  58  is continued through layer  50  of silicon oxide; the etch of layer  50  continues down to the surface of the bit line contact plug  41 , exposing the surface of plug  41 , using the layer  38  of silicon nitride as the etch stop layer; note in FIG. 8 that layers of silicon oxide dielectric  50  remain in place overlying facing, outside surfaces of the CUB capacitors  61  and  63   
     the patterned and developed layer  60  of photoresist is removed from the surface of the etched second electrodes  59  of the CUB capacitors, and 
     a layer  62  of non-doped polysilicon, also referred to as flat-poly or F-poly, is deposited over the exposed surfaces, that is the surface of the etched second electrodes  58  of the CUB capacitors  61  and  63  and the inside surfaces of the opening  59  that has been created through the layer  50  of silicon oxide. 
     Layer  62  of F-poly can be deposited using low-pressure vapor deposition (LPCVD) using, for example, silane (SiH 4 ), to a thickness of between about 200 and 500 Angstrom. The layer of polysilicon is preferably deposited by LPCVD using a reactant gas such as SiH 4  or SiH 2 Cl 2 , typically in a temperature range of between 600 and 650 degrees C. 
     Proceeding with the invention, FIG. 9 shows the processing steps of: 
     removing the deposited layer  62  of flat-poly from the surface of the second electrode  58  of the CUB capacitors  61  and  63 ; this etch can be performed using carbon tetrofluoride (CF 4 )/CHF 3  as etchant gas, using a commercially available parallel plate RIE etcher or an Electron Cyclotron Resonance (ECR) plasma reactor; this etch results in leaving in place layers of flat-poly over the inside sidewalls of opening  59  forming sidewall spacers inside the opening  59   
     a layer  64  of low-pressure tetra-ethyl-ortho-silicate (LPTEOS) has been deposited over the sidewall spacers  62  inside opening  59  and over the surface of the exposed surface of the second electrode of the CUB capacitors  61  and  63 , using methods of CVD, to a thickness between about 500 and 1500 Angstrom. 
     FIG. 10 shows a cross section wherein: 
     the layer  64  of LPTEOS has been removed from the surface of the second electrode  58  of the CUB capacitors  61  and  63  using methods of Reactive Ion Etch (RIE) and applying carbon tetrofluoride (CF 4 )/CHF 3  as etchant gas; the layer  64  of LPTEOS remains in this manner in place overlying layer  62  and becomes part of the spacers that are formed over the sidewalls of opening  59 ; it is clear from the cross section that is shown in FIG. 10 that the spacers overlying the sidewalls of opening  59  comprise three layers, that is layer  50  of silicon oxide, layer  62  of F-poly and layer  64  of LPTEOS; further shown in cross section in FIG. 10 is 
     layer  66  of D-polysilicon, which is deposited to a thickness between about 1500 and 3000 Angstrom and is deposited such that the opening  59  is completely filled with layer  66  of D-polysilicon. 
     Layer  66 , FIG. 10, has been highlighted as comprising D-polysilicon, layer  66  is not limited to D-polysilicon but can also comprise a metal film since this layer is an interconnect layer. In view of this, the dopant concentration (of for instance PH 3 ) should be as high as possible. 
     FIG. 11 shows a cross section after the surface of deposited layer  66  has been polished using methods of CMP or an RIE etchback. It is clear from the cross section that is shown in FIG. 11 that an “isolated plug”  68  comprising D-polysilicon has been formed aligned with the bit line contact plug  41 . Layers  50  of silicon oxide, layer  62  of F-poly and layer  64  of LPTEOS surround the isolated plug  58 . Key to the invention is the presence of ring  64  of LPTEOS which, being a ring comprising tetra-ethylortho-silicate (TEOS) based oxide, can be removed from around the isolated plug  68 . 
     FIG. 12 shows a cross section after layer  64  of LPTEOS has been removed from around the isolated plug  78 . This removal is achieved by wet buffer oxide etching using diluted HF (HF solution). This wet buffer oxide etch or HF dip is a one time process performed at atmospheric pressure using a conventional wet bench process with a ratio of H 2 O:HF of between about 20:1 and 100:1. Openings  65  and  67  are in this manner created, the removal of layer  64  removes an oxide ring of about 0.05 to 0.15 μm width from around plug  68 . 
     Further remains to seal to openings  65  and  67  that have been created surrounding the isolated plug  68 . This is accomplished, FIG. 13, by depositing a layer  78  of PETEOS over the surface of the second electrode  58  of the capacitors  61  and  63 . PETEOS when deposited is known to have poor step coverage or “overhang” which in this case results in the openings  65  and  67  being closed off be the “overhanging” PETEOS. 
     Further shown in cross section in FIG. 13 is the deposition and developing of a layer  80  of photoresist. The developing of the layer  80  of photoresist has created an opening  81  in layer  80  of photoresist that aligns with the bit line contact plug  41 . 
     A top view of the bit line plug which has been created before the deposition of the layer  66  of PETEOS is shown in FIG. 14, which shows: 
       68 , the surface of the bit line contact 
       70 , the top plate of poly layer  58   
       72 , the cell capacitor 
       74 , the air gap  65 / 67 , and 
       76 , the F-poly  62 . 
     FIG. 15 shows in cross section after layer  78  of dielectric has been etched in accordance with opening  81  that has been created in layer  80  (FIG. 13) of photoresist, the layer  80  (FIG. 13) of patterned photoresist has been removed from the surface, a layer  82  of metal has been deposited, filling opening  81  and contacting the surface of bit plug  68  (FIG.  11 ). The patterning of layer  82  (not shown) creates the bit lines of the DRAM cells of the invention. 
     The invention can be summarized as follows: 
     a silicon semiconductor substrate is provided, STI regions have been created in the surface of the substrate that define and bound the active surface region of the substrate; gate electrodes have been provided over the active region of the substrate; of special interest are storage node contact and bit line contact that have been provided on the active surface region of the substrate 
     a first layer of dielectric is deposited over the surface of the substrate, including the surface of the gate electrodes that have been created in the active surface region of the substrate; a layer of etch stop material is deposited over the surface of the first layer of dielectric 
     openings are created in the first layer of dielectric that align-with the bit line (one opening) and capacitor (charge node, two openings) contacts on the surface of the substrate; the openings are filled with doped polysilicon, the deposited polysilicon is polished creating conductive plugs through the first layer of dielectric for the charge node and bit line contacts of the DRAM cell 
     a second layer of dielectric is deposited over the surface of the etch stop layer; a patterned first layer of photoresist is created over the surface of the second layer of dielectric; the pattern of openings that have been created in the second layer of dielectric aligns with the node contacts of the DRAM cell; CUB capacitors are to be created in these openings 
     the second layer of dielectric is etched in accordance with the openings that have been created in the first layer of photoresist, exposing the surface of the charge node contact plugs created in the first layer of dielectric; the patterned first layer of photoresist is removed, exposing the surface of the second layer of dielectric; first electrode material (HSG) is deposited and polished creating the first electrodes of the CUB capacitors; dielectric layers (ONO) are deposited over the first electrodes of the CUB capacitors 
     a layer of D-poly is deposited over the exposed surface of the second layer of dielectric and the dielectric layers of ONO 
     the layer of D-poly is etched, creating the second electrodes of the CUB capacitors; the etch is continued through the second layer of dielectric and stopped on the surface of the etch stop layer, exposing the surface of the bit line contact plug created in the first layer of dielectric, leaving in place a layer of second dielectric between the first electrodes of the CUB capacitors and the sidewalls of the opening that is created in the second layer of dielectric 
     a layer of F-poly is formed over the layer of first dielectric that has been left in place over the sidewalls of the opening created in the second layer of dielectric 
     a layer of LPTEOS is formed over the layer of F-poly over the sidewalls of the opening created in the second layer of dielectric 
     the opening created in the second layer of dielectric is fully filled with D-poly, forming a conductive plug through the second layer of dielectric 
     the layer of LPTEOS is removed from the opening created in the second layer of dielectric 
     a layer of PETEOS is deposited over the exposed surface of the second electrode of the CUB capacitors, closing the opening created in the second layer of dielectric 
     the layer of PETEOS is patterned and etched, creating an opening in the layer of PETEOS that aligns with the conductive plug formed through the second layer of dielectric, and 
     the opening that has been created in the layer of PETEOS is filled with metal, the layer of deposited metal overlying the layer of PETEOS is polished and patterned to create interconnect metal to the bit line of the DRAM cell. 
     Although the invention has been described and illustrated with reference to specific illustrative embodiments thereof, it is not intended that the invention be limited to those illustrative embodiments. Those skilled in the art will recognize that variations and modifications can be made without departing from the spirit of the invention. It is therefore intended to include within the invention all such variations and modifications which fall within the scope of the appended claims and equivalents thereof.