Abstract:
A method is provided for making capacitors for future high density circuits. The method increases capacitance while reducing the difficulty in etching the high aspect ratio holes for the capacitor node contacts. After FETs are formed in device areas, a first insulator is deposited and first contact openings are etched for the capacitor node contact. First polysilicon (polySi) plugs are formed in the first contact openings. An etch-stop layer and a second insulating layer are deposited. Second contact openings are aligned over and etched in the second insulating layer to the first polySi plugs. Second polySi plugs are formed in the second contact openings. Openings for capacitors, aligned over and wider than the second polySi plug, are etched in the second insulating layer. The capacitors are completed by forming bottom electrodes with a thin dielectric layer in the capacitor openings and forming a top electrode. This two polysi plug method reduces the need to etch a single high aspect ratio (deep) contacts holes. The second polysi plug also serves as a pillar for increased capacitance. The second contact openings and capacitor openings are etched using a very controllable etch to the etch-stop layer without disturbing the underlying DRAM structure. This allows capacitor design changes for future product generation beyond 0.25 um.

Description:
BACKGROUND OF THE INVENTION 
     (1) Field of the Invention 
     The present invention relates to the fabrication semiconductor integrated circuits, and more particularly to a method of fabricating random access memory (DRAM) devices, having stacked capacitors with an additional polysilicon plug to reduce the aspect ratio for capacitor node contact openings while increasing capacitance. 
     (2) Description of the Prior Art 
     Advances in Ultra Large Scale Integration (ULSI) technologies are dramatically increasing the circuit density on the semiconductor chip. This increase in density is due in part to advances in high-resolution photolithography and anisotropic plasma etching in which the directional ion etching results in essentially bias-free replication of the photoresist image in the underlying patterned layers, such as in polysilicon and insulating oxide layers and the like. 
     One such circuit type where this high-resolution processing is of particular importance is the dynamic random access memory (DRAM) circuit. This DRAM circuit is used extensively in the electronics industry, and particularly in the computer industry for electrical data storage. The DRAM circuits consist of an array of individual memory cells, each cell consisting of an access transistor, usually a field effect transistor (FET), and a single storage capacitor. Information is stored on the cell as charge on the capacitor, which represents a unit of data (bit), and is accessed by read/write circuits on the periphery of the DRAM chip. After the year 2000 the number of these cells on a DRAM chip is expected to exceed a gigabit. To achieve this high density and still maintain a reasonable chip size, the individual cells on the chip must be significantly reduced in size. As these individual memory cells decrease in size, so must the area on the cell that the storage capacitor occupies. The reduction in the storage capacitor size makes it difficult to store sufficient charge on the capacitor to maintain an acceptable signal-to-noise level, and circuits require shorter refresh cycle times to retain the necessary charge level. One method of overcoming this size problem is to build stacked capacitors that extend vertically over the cell areas to increase the electrode capacitor area while confining the capacitor within the cell area. 
     However, as the minimum feature sizes decrease to less than a quarter-micrometer (0.25 um), it becomes increasing difficult to built reliable stacked capacitors without increasing process complexity and manufacturing cost. One process complexity is the need to etch contact holes in insulators with increasing aspect ratios (depth/width). It is difficult to etch these deep holes without over-etching that damages the substrate causing excessive junction leakage at the capacitor node contact. 
     For these submicrometer devices it is also important to provide planar surfaces to facilitate the formation of high resolution photoresist etch masks that require a more shallow depth of focus (DOF) during the photoresist exposure. Planar surfaces are also required because of the very directional etching, since patterning layers, such as polysilicon and metals, by directional etching can otherwise result in unwanted residue at steps (recesses) on non-planar surfaces. However, planarizing process, such as chemical-mechanical polishing or planarizing etch backs, are time consuming and costly. Therefore it is desirable to minimize the number of planarizing steps and to reduce the aspect ratio for contact holes on DRAM circuits. 
     Numerous methods of making DRAM circuits with stacked capacitors having increased capacitance have been reported in the literature. The following U.S. patents describe several methods for making stacked capacitors. Wang et al. in U.S. Pat. No. 5,702,989 describe a method for making a DRAM using a single polysilicon plug as the capacitor node contact and also serves as a center column in the capacitor to increase capacitance. However, this single plug requires etching very deep contact contacts with very high aspect ratios (depth/width) and is difficult to achieve without excessive over etching in the insulating layer. Another approach is described by Chao in U.S. Pat. No. 5,863,821 in which a contact hole is etched through a multilayer to the substrate. This is also difficult to achieve without over-etching. Tseng in U.S. Pat. Nos. 5,854,105 and 5,843,821 describe methods for making DRAMs with single polysilicon plugs in a planar insulating on which are fabricated stacked capacitors. However, further process would require an insulating layer over the capacitors that would need to be planarized. In U.S. Pat. No. 5,888,865 Lin describes a method for making a DRAM capacitor using a single polysilicon plug that also serves as a portion of the stacked capacitor. However, Lin etches contact holes through a relatively thick multilayer to the substrate which can result in over-etch and substrate damage (leakage currents). 
     However, there is still a need to improve the fabrication of DRAM devices with high capacitance for future product generation below the 0.25 um feature sizes and to make the process more manufacturable and cost effective. 
     SUMMARY OF THE INVENTION 
     It is a principal object of the present invention to provide a method for fabricating DRAM memory cells with stacked capacitors having increased capacitance that are more manufacturable and cost effective. 
     It is another object of this invention to achieve the principal object above by using an additional second (upper) polysilicon plug, as a pillar, that is aligned over a first (bottom) polysilicon plug used as the capacitor node contact. The use of two polysilicon plug reduces the etch depth of the contact openings for better control when making sub-quarter micrometer (&lt;0.25 um) DRAM product. This additional pillar also results in increased capacitor height (increased capacitance) with excellent capacitance control while avoiding plasma etch damage to the substrate in the node contact openings. 
     It is still another object of this invention to use this additional upper polysilicon plug to independently optimize the total surface area for capacitor enhancement of future product generation beyond 0.25 um without the need to alter (disturb) the underlying DRAM structure. 
     The above objects of this invention are achieve by first providing a semiconductor substrate (wafer) composed of single crystalline silicon. A field oxide is formed in and on the substrate surrounding and electrically isolating an array of device areas in which are formed the semi-conductor devices. The most commonly used devices are field effect transistors (FETs). For high density circuits a more advanced field oxide isolation is utilizes, commonly referred to a shallow trench isolation (STI). The STI is formed by etching a shallow trench in the silicon substrate and filling the trench with an insulating material, such as a chemical vapor deposited (CVD) silicon oxide (SiO 2 ). The SiO 2  is polished or etched back to form a STI that is planar with the substrate surface. The FETs are formed by first forming a thin gate oxide on the device areas. A conductively doped polysilicon layer and a silicide layer are deposited to form a polycide layer. The polycide layer is then patterned to form word lines for the DRAM cells, and portions of the patterned polycide extend over the device areas and serve as the FET gate electrodes. Concurrently the patterned polycide layer also serves as local inter-connection for the peripheral circuits on the DRAM chip. Lightly doped drains (LDDs) are formed next in the substrate adjacent to the gate electrodes, usually by ion implantation, and sidewall spacers are formed on the gate electrodes by depositing and blanket etching back an insulating layer, such as SiO 2  or SiO 2  and Si 3 N 4 . After the LDDs and sidewall spacers are formed, the FETs in the peripheral circuits are completed by forming heavily doped source/drain contact regions adjacent to the sidewall spacer to provide low contact resistance. 
     Continuing with the process, the improved stacked capacitors are now fabricated. A first insulating layer is deposited on the substrate, and is planarized. The first insulating layer is a silicon oxide (SiO 2 ) or a doped oxide such as a borophosphosilicate glass (BPSG). First contact openings are etched in the first insulating layer to the source/drain areas in the DRAM cells for the capacitor node contacts and bit line contact. A first polysilicon plugs are formed in the first openings for capacitor node contact and bit line contact by depositing an in situ doped poly-silicon layer and etching back or chemical-mechanical polishing back to the surface of the first insulating layer. A blanket etch stop layer, such as Si 3 N 4 , is deposited on the first insulating layer and over the first polysilicon plugs. A relatively thick second insulating layer is then deposited on the etch stop layer. 
     Referring now more specifically to the method of this invention, second contact openings are etched in the second insulating layer and the etch stop layer to the first polysilicon plugs in the capacitor node contact openings. A conductively doped polysilicon layer is deposited and etched back or polished back to the second insulating layer to form second polysilicon plugs in the second contact openings. Next, a photoresist etch mask and anisotropic plasma etching are used to etch openings for capacitors in the second insulating layer and the etch stop layer. These openings are aligned over and are wider than the second polysilicon plugs. These openings, hereafter referred to as capacitor openings, result in a recesses having free standing second polysilicon plugs that form center pillars for the stacked capacitors. By including this second polysilicon plug it is possible to eliminate the need to etching deep-high aspect ratio contact openings to the substrate, that would otherwise result in over-etch damage to the shallow diffused junctions in the substrate. Also the capacitor height can be independently and more accurately controlled. The etch stop layer allows the second contact openings and the capacitor openings be etched accurately to the first polysilicon plug without over etching the underlying first insulating layer. The capacitor openings can be redesigned to tailored the capacitors for future sub-quarter micrometer (&lt;0.25 um) product without affecting the underlying DRAM structure. Continuing with the process, a conformal in situ doped first polysilicon layer is deposited and polishing back to the top surface of the second insulating layer to form the capacitor bottom electrodes in the capacitor openings having a pillar formed from the second polysilicon plug to increase capacitance. To further increase capacitance a hemispherical silicon grain (HSG) layer is formed on the bottom electrode. A relatively thin interelectrode dielectric layer having a high dielectric constant is then formed on the bottom electrode. A doped second polysilicon layer is deposited sufficiently thick to fill the remaining spaces in the capacitor openings and is patterned to form capacitor top electrodes and complete the stacked capacitors. The DRAM device (circuits) are now completed to the first level of electrical interconnections. A third insulating layer, such as SiO 2 , is deposited. Via holes are etched in the third insulating layer to the device areas of the peripheral circuits, to the bit line contact plugs (first polysilicon plugs), and to the capacitor top electrodes. A metal plug is formed in the via holes by depositing a metal, such tungsten (W), and chemical-mechanical polishing back the W to the third insulating layer. A first metal, such as an aluminum/copper (Al/Cu) alloy, is deposited and patterned to form the first level of interconnections for the DRAM devices. Although the method is described for DRAM devices, these capacitors can be made for merged DRAM/logic circuits. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The objects and other advantages of this invention are best understood with reference to the attached drawing and embodiment that follows. 
     FIGS.  1 , 2 , 3 , 4 , 5 , 6  and  7  show schematic cross-sectional views through a portion of the DRAM device having an array of memory cells depicting the sequence of process steps for forming the stacked capacitors with two polysilicon plug by the method of this invention. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Now in keeping with the objects of the invention, the method for forming a DRAM stacked capacitor using two polysilicon plugs is covered in detail. These DRAM devices with improved capacitors can be fabricated using FET structures that are currently utilized in the manufacture of DRAMs. Therefore, only those details of the underlying substrate structure will be described that are necessary for understanding the current invention. It should also be well understood by those skilled in the art that by including additional processing steps, other types of devices can also be included on the DRAM chip. For example, by providing N and P doped wells, both P-channel and N-channel FETs can be formed for fabricating CMOS circuits, as are commonly used in the peripheral circuits of the DRAM chip. Further the process is applicable to embedding (or merging) these DRAM devices with logic circuits. 
     Referring now to FIG. 1, a cross-sectional view is shown of a portion of a semiconductor substrate  10  having a partially completed DRAM cell . A portion of the peripheral circuits of the DRAM device is depicted in the left side of the figures, and is labeled P, and the portion of the memory cell is depicted on the right side of the figures and labeled C. The semiconductor substrate  10  commonly used in the industry is composed of a P-type single-crystal silicon having a &lt;100&gt; crystallographic orientation. A relatively thick Field OXide  12  (FOX) is used to surround and electrically isolate the device areas. Typically for the more advanced high density circuits, the most commonly used field oxide in the industry is a shallow trench isolation (STI). Briefly, the method for making the STI  12  consist of etching shallow trenches in the field oxide regions while using a patterned stress-release oxide (pad oxide) layer and a thicker hard mask layer to protect the devices areas. The pad oxide is typically a thermal silicon oxide (SiO 2 ) and the hard mask is a silicon nitride (Si 3 N 4 ) layer. The trenches are typically etched to a depth of about 2000 and 5000 Angstroms using for example anisotropic plasma etching. After cleaning and growing a good thermal oxide on the trench surface, an insulating layer, such as a chemical vapor deposited SiO 2  (CVD-SiO 2 ) is deposited on the substrate and chemical-mechanical polished back to the hard mask. The hard mask and pad oxide (not shown in FIG. 1) are then removed to leave the STI  12  in the trenches essentially planar with the substrate surface, as depicted in FIG.  1 . 
     Continuing in FIG. 1, The field effect transistors (FETs) are fabricated next in and on the device areas for the DRAM cell, the typical transistor used is the N-channel FET and is now briefly described. The silicon surface is carefully cleaned, and a good quality thermal oxide is grown to form the gate oxide  14 . Only the portion of the gate oxide  14  that remains after further process is shown under the gate electrodes. Typically the gate oxide is grown to a thickness of between about 30 and 100 Angstroms. The gate electrodes  16  are formed next from a patterned polycide (polysilicon and silicide) layer  16 . The polycide layer is composed of a doped polysilicon layer  16 A and a refractory metal silicide layer  16 B. The top polycide layer  16 B is included to increase the electrical conductivity and improve circuit performance. The polysilicon layer  16 A is typically deposited by low-pressure chemical vapor deposition (LPCVD) using, for example, silane (SiH 4 ) as the reactant gas. The polysilicon is then appropriately doped by ion implantation to increase the electrical conductivity, and usually is doped with arsenic (As) or phosphorus (P) to a dopant concentration of between about 1.0 E 15 and 1.0 E 16 atoms/cm 3 . The silicide  16 B is typically a refractory metal silicide, such as tungsten silicide (WSi 2 ), and is usually deposited by CVD using a reactant gas mixture such tungsten hexafluoride (WF 6 ) and silane (SiH 4 ) and is deposited to a thickness of between about 500 and 1500 Angstroms. The polycide layer  16  (layers  16 A and  16 B) is then patterned using conventional photolithographic techniques and anisotropic plasma etching to form the gate electrodes  16  over the device areas. Portions of the patterned polycide layer are also used as local interconnections over the STI  12  regions which include the word lines for the cell areas, as shown in FIG.  1 . 
     Next, lightly doped source/drain regions  17 (N − ) are formed adjacent to the gate electrodes  16  usually by implanting a N-type dopant, such as arsenic or phosphorus. For example, a typical implant might consist of a phosphorus P 31  at a dose of between about 1.0 E 13 and 1.0 E 14 atoms/cm 2  and with an ion energy of between about 15 to 50 Kev. As is commonly used in the semiconductor industry a photolithographic mask can be used to avoid implanting in areas not requiring the implant. 
     After forming the lightly doped source/drain areas  17 (N 31 ), sidewall spacers  20  are formed on the gate electrodes  16 . The spacers  20  are formed by depositing a conformal blanket SiO 2  layer, and anisotropically etching back to the substrate surface. For example, the SiO 2  can be deposited by chemical vapor deposition using tetraethosiloxane (TEOS) at a temperature in the range of between about 650 and 900° C., and the etchback can be accomplished using reactive ion etching (RIE) and an appropriate etchant gas such as carbon tetrafluoride (CF 4 ) and hydrogen (H 2 ). The FETs are now completed by forming heavily doped source/drain contact areas  19 (N + ), as shown in FIG.  1 . For example, arsenic (As 75 ) can be implanted to achieve a final dopant concentration of between about 1.0 E 19 and 1.0 E 20 atoms/cm 3 . Next a barrier layer  22  is deposited which also serves as an etch-stop layer. Typically layer  22  is Si 3 N 4  and is deposited by low pressure CVD (LPCVD) to a thickness of between about 100 and 500 Angstroms. 
     Still referring to FIG. 1, and continuing with the process the capacitors are made next. A first insulating layer  24  is deposited on the substrate and planarized. The first insulating layer  24  provides electrically insulation over the FET devices on the substrate  10  and provides a base to supports the capacitors. Layer  24  is preferably a silicon oxide (SiO 2 ) and is deposited using LPCVD and a reactant gas such as tetraethosiloxane (TEOS) or TEOS and ozone. Alternatively, layer  24  can be a doped oxide, such as a borophosphosilicate glass (BPSG) deposited by LPCVD using TEOS, and is doped with boron and phosphorus during the silicon oxide deposition. The first insulating layer  24  is then planarized. For example, layer  24  can be planarized using chemical/mechanical polishing (CMP) to provide global planarization. The thickness of layer  24  after planarizing is preferably between about 3000 and 6000 Angstroms over the underlying FET gate electrodes  16 . Conventional photolithographic techniques and anisotropic plasma etching are used to etch first contact openings  2  in the first insulating layer  24  and in the barrier layer  22 . The openings  2  are etched aligned over and to the source/drain contact region  17 (N) in each of the memory cell device areas (portion C) for the capacitor node contacts and bit line contacts. A polysilicon layer  26  is deposited and polished back to the surface of the first insulating layer  24  to form first polysilicon plugs  26 A for the capacitor node contacts and first polysilicon  26 B for the bit line contacts. The polysilicon layer  26  is preferably deposited by LPCVD using for example silane (SiH 4 ) as the reactant gas and is deposited to a thickness sufficient to fill the openings  2 . The polysilicon layer  26  is doped in situ during deposition using phosphine (PH 3 ) as the dopant gas, and layer  26  is doped to a preferred concentration of between about 1.0 E 19 and 1.0 E 21 atoms/cm 3 . The layer  26  is then chemical-mechanical polished back to form the polysilicon plugs  26 A and  26 B in openings  2 . 
     Next, as shown in FIG. 1, A blanket etch stop layer  28  is deposited on the first insulating layer  24  and over the first polysilicon plugs  26 A and  26 B. Layer  28  is preferably composed of silicon nitride (Si 3 N 4 ), and is deposited by LPCVD using a reactant gas mixture such as dichlorosilane (SiCl 2 H 2 ) and ammonia (NH 3 ). The preferred thickness of layer  28  is between about 100 and 500 Angstroms. A second insulating layer  30  is deposited on the etch-stop layer  28 . Layer  30  is also composed of SiO 2  or BPSG, and is deposited by LPCVD to a preferred thickness of between about 5000 and 10000 Angstroms that will determine the height H of the stacked capacitor. 
     Referring now to FIG. 2, and more specifically to the method of this invention, a photoresist etch mask and plasma etching is used to etch second contact openings  4  in the second insulating layer  30  selectively to the etch stop layer  28 . The openings  4  are aligned over the capacitor node contact plugs  26 A. The etching is preferably carried out using RIE or a high density plasma etching and an etchant gas mixture, such as C 2 F 6 ,C 4 F 8  and CH 2 F 2 , which etches SiO 2  to Si 3 N 4  having an etch selectivity of greater than about 20:1. This allows the thick second insulating layer  30  to be over etched at the Si 3 N 4  layer  26  without significant over etching of the underlying structure (first insulating layers  24  or polysilicon plugs  26 A). The thinner etch stop layer  28  can then be etched to the first polysilicon plugs  26 A in the capacitor node contact openings  4  , without significant over etching. For example, the Si 3 N 4  layer can be etched using RIE and a etchant gas mixture, such as CH 2 F 2  and O 2 . 
     Still referring to FIG. 2, a conductively doped polysilicon layer  32  is deposited and plasma etched back or polished back to the second insulating layer  30  to form second polysilicon plugs  32  in the second contact openings  4 . Since these capacitor node contacts are formed in two etch steps (contact openings  2  and  4 ) the aspect ratio of each etched hole is significantly reduced, and is easier and more reliably to form sub-quarter micrometer (&lt;0.25 um) devices. The second polysilicon plug also services as a center pillar for the stacked capacitor to further increase capacitance, as will soon become apparent. 
     Referring to FIG. 3, conventional photolithographic techniques and anisotropic plasma etching are use to selectively etch openings  6  in the second insulating layer  30  to the etch stop layer  28 . The openings  6  are aligned over and are wider than the second polysilicon plug  32  The exposed etch-stop layer  28  in the openings  6  is then etched to the first insulating layer  24  and polysilicon plugs  26 A. The etching is similar to method used for etching the openings  4  above, and therefore are etched without significant over-etching. These openings  6 , referred to as capacitor openings, result in a recesses having free standing second polysilicon plugs  32  that form center pillars for the stacked capacitors. Since the capacitor height H is determined by the thickness of the second insulating layer  30  and etch stop layer  28  the capacitance can be accurately controlled. Since the width of the capacitor openings  6  and the width of second polysilicon plug  32  can be more accurately controlled, the capacitance can be tailored for each succeeding product generation after the 0.25 um generation. These advanced capacitor structures can be achieved without adversely affecting the underlying DRAM structure. 
     Referring to FIG. 4, an situ doped conformal first polysilicon layer  34  is deposited and polishing back to the top surface of the second insulating layer  30  to form the capacitor bottom electrodes  34  in the capacitor openings  6 . The polysilicon layer  34  is deposited using LPCVD and silane and is deposited to a thickness of between about 500 and 1000 Angstroms. The polysilicon layer  34  is preferably doped in situ by adding a dopant gas, such as phosphine (PH 3 ) during the LPCVD deposition, and is doped to a preferred concentration of between 1.0 E 19 and 1.0 E 21 atoms/cm 3 . To further increase the capacitance the layer  34  can be roughened, for example by forming a Hemispherical Silicon Grain (HSG) surface on layer  34 . Still referring to FIG. 4, a thin interelectrode dielectric layer  36  (not shown as a separate layer) is formed on the surface of the capacitor bottom electrode  34 . The thin dielectric layer  36  has a thickness preferably equal to an effective silicon oxide thickness of between about 40 and 50 Angstroms, and is composed of a material having a high dielectric constant that is compatible with the polysilicon processing, and is continuous and essentially pinhole free. One of the preferred interelectrode dielectric layer is composed of silicon oxide-silicon nitride (ON) or a silicon oxide-silicon nitride-silicon oxide (ONO) layer. For example, the surface of the polysilicon bottom electrode can be thermally oxidized to form the silicon oxide, and then a thin conformal silicon nitride layer can be deposited using LPCVD to form the ON layer. To form the ONO layer, the exposed surface of the Si 3 N 4  layer can then be reduced in an oxidizing ambient at elevated temperatures. 
     As shown in FIG. 5, a doped second polysilicon layer  38  is deposited to form capacitor top electrodes. The second polysilicon layer  38  is deposited by LPCVD similar to the first polysilicon layer  34 , but to a thickness sufficient to fill the remaining space in the openings  6  between the sidewalls  34  and the pillars  32 , and more specifically to a thickness of between about 800 and 1000 Angstroms. Conventional photolithographic techniques and plasma etching are used to pattern the capacitor top electrodes, as depicted in FIG. 6 
     The DRAM device (circuits) are now completed to the first level of electrical interconnections, as shown in FIG. 7. A third insulating layer  40  is deposited to electrically insulated the top electrodes  38 . Layer  40  is preferably a LPCVD SiO 2 , and is deposited to a thickness of between about 3000 and 5000 Angstroms. Via holes  8  are etched in the third insulating layer  40  to the source/drain contact areas device areas in the peripheral portions, to the bit line first polysilicon plugs (landing plugs)  26 B, and to the capacitor top electrodes  38  in the cell portions C. Metal plugs is formed in the via holes  8  by depositing a metal  42 , such tungsten (W) and chemical-mechanical polishing the W to the third insulating layer  40 . Typically, the tungsten  42  is deposited by CVD using WF 6  as the reactant. A first metal, such as an aluminum/copper (Al/Cu) alloy  44  is deposited. The Al/Cu can be deposited by physical vapor deposition (PVD), such as by sputter deposition from an Al/Cu target, and is typically deposited to a thickness of between about 4000 and 6000 Angstroms. A photoresist mask (not shown) and anisotropic plasma etching are used to pattern the first level metal  44  to form the local interconnection  44 A for the peripheral circuits C, and the bit lines  44 B. Although the method is described for DRAM devices, these capacitors can also be made for merged DRAM/logic circuits. 
     While the invention has been particularly shown and described with reference to the preferred embodiment thereof, it will be understood by those skilled in the art that various changes in form and detail may be made without departing from the spirit and scope of the invention.