Patent Abstract:
A electrical device is formed by methods that are disclosed for the fabrication thereof, the electrical devices being novel polysilicon structures having increased surface areas to achieve lower resistances after silicidation. The structures are applicable, for example, to semiconductor interconnects, polysilicon gate, and capacitor applications. The inventive method provides additional means of obtaining suitable sheet resistivity and resistances for deep submicron applications. Techniques are disclosed for improving the conductivities of a silicided gate structure, a silicided interconnect structure, and capacitor component structures, each of such are situated on a substrate assembly, such as a semiconductor wafer.

Full Description:
BACKGROUND OF THE INVENTION 
     This application is a divisional application of U.S. patent application Ser. No. 09/336,885, filed on Jun. 18, 1999, which is a divisional application of U.S. patent application Ser. No. 08/733,321, filed on Oct. 17, 1996, now U.S. Pat. No. 5,981,367, which issued Nov. 9, 1999, both of which are incorporated herein by reference. 
    
    
     1. The Field of the Invention 
     The present invention relates the manufacture of a semiconductor device on a substrate assembly, where the substrate assembly is a substrate having one or more layers or structures formed thereon. More specifically, the present invention relates to the fabrication of a polysilicon structure used in the manufacture of a semiconductor device on a substrate assembly. Even more specifically, the present invention relates to techniques for improving the conductivities of a silicided gate structure and a silicided interconnect structure on a substrate assembly. 
     2. The Relevant Technology 
     Polycrystalline silicon (polysilicon) is the preferred material for gate electrodes in MOSFET structures. Polysilicon is advantageous over metal gate electrodes as it can withstand much higher subsequent processing temperatures before eutectic temperatures are reached. Polysilicon is readily deposited on bulk silicon or SiO2 using low pressure chemical vapor deposition (LPCVD), and the resistivities of doped polysilicon films are less than those of doped epitaxial or bulk silicon layers. 
     As the drive toward integrating more active devices on a single integrated circuit necessitates the fabrication of increasingly small MOSFET structures, the resistance of the MOSFET gate becomes a limiting factor in device speed. As such, it is beneficial to use materials with the lowest possible sheet resistivities for making contact with the polysilicon gate structure. To this end it is well known that refractory metal silicides can be readily formed on polysilicon MOSFET gate structures using conventional sputtering, deposition, and annealing processes. The refractory metal suicides have low sheet resistivities after annealing and also form low resistance ohmic contacts with commonly used interconnect metals. 
     Of all the available silicides, titanium disilicide (TiSi 2 ) is preferred due to its inherent low sheet resistivity when annealed to the C54 crystalline phase thereof. To obtain the desired low resistivity requires high temperature annealing in a range from about 700° C. to about 1100° C. Numerous techniques for creating TiSi 2  films on MOSFET gate, source, and drain electrodes are used to obtain the desired low sheet resistivity. An example of such a technique is the chemical vapor deposition (CVD) of either pure titanium metal or stoichiometric titanium silicide (TiSi x ), with subsequent annealing steps to convert the layer to TiSi 2  in the C54 crystalline phase thereof 
     Limitations are known to exist with respect to the processing of TiSi x  films, particularly as MOSFET transistor geometries are scaled down to deep submicron dimensions. It is known that the lowest obtainable sheet resistivities of annealed TiSi 2  films are only achieved when the silicide completely transforms to the C54 crystalline phase. It has more recently been discovered that achieving complete C54 crystalline phase transformation as conductor line width dimensions are scaled below about 0.5 microns requires increasingly higher processing temperatures. Such higher processing temperatures create problems such as induced layer defects due to the agglomeration of the silicided metal, and other problems. An agglomeration of a TiSi x  film on a polysilicon gate having a length below about 0.25 microns can cause an increase in resistance from a normal 1-2 Ohms per square to 20-30 times the resistance. 
     Accordingly, it would be an advance in the art to fabricate semiconductor interconnects, conductors, and transistor gates using established, reliable processing methods and materials, each of which have a suitably low resistivity so that overall semiconductor device speed and performance is maintained when such structures are scaled down to deep submicron dimensions. 
     SUMMARY OF THE INVENTION 
     The present invention describes novel methods of making gate structures and interconnect line structures having complex surfaces, which are useful in the fabrication of semiconductor devices. The geometries of the structures, when combined with fabrication methods disclosed, provide for significantly increased areas of exposed polysilicon or amorphous silicon material on which refractory metal layers can be deposited. As such, there is a significant increase in the total cross-sectional area of the regions over which polycide regions (e.g. refractory metal silicides) may potentially be formed in subsequent annealing steps. The increased cross-sectional area of the polycide regions compensates for the increase in polycide sheet resistivity which is observed as semiconductor device geometries are scaled to deep submicron line widths, thereby reducing the effective series resistance of the gate or conductor line structures and of the contact interfaces thereto. Furthermore, when the refractory metal layer consists of titanium metal or as-deposited titanium silicide, the increased surface area may contribute to a lowering of processing temperatures required to achieve a complete transformation of the titanium silicide to the C54 crystalline phase, thereby lowering the overall sheet resistivity in addition to increasing the surface area. The increase in surface area of polycide regions can be accomplished by forming various structures having surfaces upon which the polycide regions are formed. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     A more particular description of the invention briefly described above will be rendered by reference to specific embodiments and applications thereof which are illustrated in the appended drawings. Understanding that these drawings depict only typical embodiments and applications of the invention and are not therefore to be considered to be limiting of its scope, the invention will be described and explained with additional specificity and detail through the use of the accompanying drawings in which: 
     FIGS. 1A-1F are a sequence of cross-sectional views of a simple non-planar polysilicon structure, illustrating the development of the polysilicon structure, as it progresses through fabrication steps described below. 
     FIGS. 2A-2B depicts perspective views that illustrate a principle of the invention described herein by which the effective conductive surface area of the polysilicon structure is increased. 
     FIGS. 3A-3I are a sequence of cross-sectional views of a preferred embodiment of the novel transistor structure of the invention described herein, illustrating the development of the novel transistor structure, as it progresses through the fabrication steps described below. 
     FIGS. 4A-4C are a sequence of cross sectional views of an alternate embodiment of the novel transistor structure of the invention described herein, illustrating the development thereof as it progresses through the fabrication steps described below. 
     FIG. 5 is a top planar view of a DRAM device with a folded bit line architecture having alternating columns of islands, and therein depicting field oxide regions, access transistor gates, storage nodes, active areas, digit nodes, and a contact, wherein the wordlines depicted are formed according to the inventive methods and have both transistor gate structures and parasitic field devices. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Preferred embodiments of the invention are shown and described in the disclosure below, simply by way of illustration of the best mode contemplated for carrying out the invention. As will be realized, the invention is capable of other and different embodiments, and its several details are capable of modifications in various respects, all without departing from the invention. Accordingly, the drawings and description are to be regarded as illustrative in nature, and not as restrictive. 
     FIGS. 1A-1F represent a fabrication sequence for a simple structure which may be formed using the concepts disclosed in the present invention in which a gate structure is formed upon a substrate assembly. The term substrate assembly is intended herein to mean a substrate having one or more layers or structures formed thereon. As such, the substrate assembly may be, by way of example and not by way of limitation, a doped silicon semiconductor substrate typical of a semiconductor wafer. 
     In FIG. 1A, a first silicon layer  14  is deposited on top of a base insulation layer  12  on a silicon substrate  10  of a semiconductor wafer. Base insulation layer  12  is typically an oxide layer grown directly from a base silicon substrate material on silicon substrate  10 , although base insulation layer  12  could also be a deposited oxide layer and the base silicon substrate material on silicon substrate  10  could also be an epitaxial silicon layer or region. Preferably, base insulation layer  12  will have a thickness in a range from about 40 Angstroms to about 150 Angstroms, and preferably from about 90 Angstroms to about 100 Angstroms. First silicon layer  14  could be either polysilicon or amorphous silicon and its composition would depend on other device and process factors. First silicon layer  14  will typically be deposited by a sputtering or chemical vapor deposition (CVD) process and has a preferred thickness of about 1500 Angstroms. 
     First refractory metal layer  16  is then deposited on silicon substrate  10  of the semiconductor wafer on top of first silicon layer  14 . First refractory metal layer  16  will typically be titanium suicide although other refractory metal suicides could be used, and will typically be deposited by a CVD process. First barrier layer  18  is then deposited on silicon substrate  10  of the semiconductor wafer on top of first refractory metal layer  16 . First barrier layer  18  will typically be a passivation or insulating material which is readily deposited such as silicon dioxide or silicon nitride, although other materials could be used. Second silicon layer  20  is then deposited on silicon substrate  10  of the semiconductor wafer on top of first barrier layer  18 . Second silicon layer  20  could be either polysilicon or amorphous silicon and its composition would depend on other device and process factors. Second silicon layer  20  will typically be deposited by a sputtering or (CVD) process and has a preferred thickness in a range from about 4000 Angstroms to about 5000 Angstroms. 
     The semiconductor wafer is then patterned with a photoresist material  22  on top of second silicon layer  20  as shown in FIG.  1 B. An etch step is then performed to etch second silicon layer  20  leaving silicon riser structures  24  as shown in FIG.  1 C. Silicon riser structures  24  serve as a mask for first barrier layer  18  during the etch. Thus first barrier layer  18  remains only under silicon riser structures  24  as shown in FIG.  1 D. 
     A second etch is then performed, etching first refractory metal layer  16  and first silicon layer  14 . After photoresist material  22  is stripped, there remains complex gate structures  32  which include base polysilicon regions  30  and silicon riser structures  24  as shown in FIG.  1 E. 
     An implantation step is then performed, creating the doped source/drain regions  34  in silicon substrate  10 . A second refractory metal layer  36  is then deposited on the semiconductor wafer as shown in FIG.  1 F. The deposition will typically be either by sputtering or by (CVD) processes. CVD achieves better coverage of exposed surfaces which are substantially vertical, such as inner vertical walls of silicon riser structures  24  and is preferred. Second refractory metal layer  36  is composed of pure titanium in the preferred embodiment although other refractory metals such as cobalt, or their stoichiometric suicides, could also be used. 
     One or more high temperature annealing steps will then be performed so that the material in first refractory metal layer  24  and second refractory metal layer  36  reacts with the polysilicon material in silicon riser structures  24  and base polysilicon regions  30  to form polycide. Material from refractory metal layer  36  that is unreacted with exposed silicon on the semiconductor wafer is then removed using a conventional etching process so that the complex gate structures  32  now appear as shown in FIG.  1 F. Temperatures during the high temperature annealing steps will be in a range from about 700° C. to about 1100° C. and will vary based on other device fabrication factors. In the preferred embodiment, the temperature chosen is sufficient to transform the titanium silicide formed into the C54 crystalline phase. 
     First barrier layer  18  is seen in FIG. 1F has having second refractory metal layer  36  thereon at area  38 . Area  38  is covered by second refractory metal layer  36  due to a phenomena know as creep. By way of example of this phenomena, as silicon mixes with the refractory metal with heightened temperature, the reaction product thereof is a refractory metal silicide that tends to grow. Seen in FIG. 1F, second refractory metal layer  36  has grown over area  38  of first barrier layer  18 , and thereafter serves as a bridge for second refractory metal layer  36  between first refractory metal layer  16  and silicon riser structure  24 . As such, second refractory metal layer  36  serves as a conductive strapping of the illustrated structures seen in FIG. 1F from top to bottom. The strapping arrangement increases the conductive surface area with a low resistivity layer on the resultant structures. 
     It will be obvious to those skilled in the art that other processing steps not disclosed here may be added which would have created regions of exposed silicon, as would be done by patterning base insulation layer  12  to create exposed regions on silicon substrate  10  of the semiconductor wafer  10 . In this event, the high temperature annealing steps would also cause regions of refractory metal layer  36  to react with the other silicon contact regions to form additional silicided regions or structures. Fabrication methods which include the additional silicided regions or structures should be considered a part of this invention. 
     The technique shown in FIGS. 1A though  1 F is particularly advantageous for forming a width of base polysilicon region  30  less than 0.25 microns. By creating complex polysilicon structures with increased surface area, the resistance of said structures is greatly reduced. Polysilicon structures, such as silicon riser structure  24 , can be integrated into fabrication of a Dynamic Random Access (DRAM) device. By way of example, and not by way of limitation, the riser structures contemplated by the present invention can be used in the formation of either a storage node component or a cell plate component of a capacitor structure found in a DRAM device. As such, the riser structure will add surface area to the capacitor so as to realize added charge strength and less time between refresh charging. 
     FIGS. 2A-2B are three dimensional cross-section drawings which illustrate the difference in surface areas between a conventional polycide gate structure as shown in FIG.  2 A and the complex gate structure which is described herein and is shown in FIG.  2 B. It is known in the art that an end-to-end resistance of a rectangular piece of conductive material is directly proportional to the number of squares of the material, said number of squares being a unitless quantity defined as: 
     
       
         
           S=L/W, 
         
       
     
     where 
     L=the end to end length of said conductive material, and 
     W=the width of said conductive material. 
     Applying this formula to a simple polysilicon structure  40  in FIG. 2A, those skilled in the art will further observe that, for typical polysilicon MOS transistor structures, the end-to-end resistance of simple polysilicon structure  40  is primarily determined by the material composition and the thickness of base silicide layer  42  along the surface of simple polysilicon structure  40 . This is due to the fact that the resistivity of base silicide layer  42  is substantially less than that of the rest of the polysilicon material which comprises simple polysilicon structure  40 . As it is now intended to show that the surface geometry of a complex polysilicon structure  44  in FIG. 2B provides for a lower end-to-end resistance than does the surface geometry of simple polysilicon structure  40  shown in FIG. 2A, it will be assumed that base silicide layer  42  covering the surface of simple polysilicon structure  40  is identical in thickness and in material composition to a riser silicide layer  48  which covers the exposed surfaces of riser polysilicon structure  46 . 
     The total width of simple polysilicon structure  40  as shown in FIG. 2A is equal to: 
     
       
           W simple= W   
       
     
     Therefore the number of squares of simple polysilicon structure  40  is equal to: 
     
       
           S simple= L/W   (1) 
       
     
     The total width of complex polysilicon structure  44 , however, is determined by the combination of the surface of simple polysilicon structure  40  and riser polysilicon structure  48  and is equal to: 
     
       
           W complex= W+ 2 *H+ ( W− 2 *U ) 
       
     
     which can be rewritten as: 
     
       
           W complex=2*( W+H−U ) 
       
     
     Therefore the number of squares of complex polysilicon structure  44  is equal to: 
     
       
           S complex= L /(2*( W+H−U ))  (2) 
       
     
     The ratio between the number of squares for the simple and complex geometries can be stated by dividing equation (2) by equation (1) which results in: 
     
       
           S complex/ S simple= W /(2*( W+H+U ))  (3) 
       
     
     Applying this relationship to a submicron gate geometry which can be developed using the invention described herein, typical values for W, H and U would be: 
     W=0.25μ H=0.5μ U=0.05μ 
     Substituting these values into equation (3) yields the relationship: 
       S complex=0.18 *S simple 
     Since the end-to-end resistance is directly proportional to the number of squares, the above calculations demonstrate that an 82% reduction in gate resistance is achievable by using the invention described herein. The percentage of reduction in gate resistance is a function of H, which can be varied according to design. An H lower than 0.5μ, such as 0.25μ, would help to reduce the height of the structure extending from the substrate assembly. In can be generally summarized that any three dimensional shape which incorporates the inventive surface area increasing aspects of the present invention will also accomplish related improvements. 
     While the embodiment described above and illustrated in FIGS. 1A-1F and FIGS. 2A-2B best illustrates the basic principle of the invention described herein, FIGS. 3A-31 illustrate an alternative embodiment of the present invention which is adapted to the fabrication of polysilicon MOSFET gate structures and which will now be described. 
     In FIG. 3A a nitride layer  50  is deposited on top of a gate oxide layer  12  of a silicon substrate  10  of a semiconductor wafer. Gate oxide layer  12  is typically an oxide layer grown directly on base silicon substrate material of silicon substrate  10 , although gate oxide layer  12  could also be a deposited oxide layer, and the base silicon substrate material of silicon substrate  10  could be an epitaxial silicon layer. A nitride layer  50  is typically deposited by a CVD process and in this embodiment is substantially composed of silicon nitride, although other materials could be used. 
     A second oxide layer  52  is then deposited on the semiconductor wafer on top of nitride layer  50 . In this embodiment, second oxide layer  52  is typically deposited by a CVD process and is substantially composed of silicon dioxide, although other materials could be used. 
     A first silicon layer  54  is then deposited on the semiconductor wafer on top of second oxide layer  52 . First silicon layer  54  could be either polysilicon or amorphous silicon and its composition would depend on other device and process factors. First silicon layer  54  is typically deposited by a sputtering or chemical vapor deposition (CVD) process and has a thickness of about 1500 Angstroms. 
     The semiconductor wafer is then patterned as shown in FIG. 3B with a photoresist layer  56  and material from nitride layer  50 , second oxide layer  52  and first silicon layer  54  is removed, leaving a gate stack  57  as shown in FIG.  3 C. The etching is performed so that nitride layer  50  is undercut. The undercut of nitride layer  50 , on each side thereof illustrated in FIG. 3C is preferably about 0.15 microns, leaving the remaining illustrated length of nitride layer  50  preferably about 0.3 microns. 
     A second silicon layer  58  is then deposited on the semiconductor wafer as shown in FIG.  3 D. Second silicon layer  58  will preferably be deposited with a CVD process so that the aforedescribed undercut areas of nitride layer  50  are filled with second silicon layer  58 . Second silicon layer  58  must also be deposited in such a manner that spacers can be formed on either side of gate stack  57  in a subsequent spacer etch of second silicon layer  58 . As such, second silicon layer  58  makes conductive contact with the vertical sides of first silicon layer  54 , so that a single complex polysilicon gate structure is formed. 
     The semiconductor wafer is then patterned and anisotropically etched so that material is removed from first silicon layer  54  leaving silicon gate structures  60  and a gate well  62  as shown in FIG. 3E. A second etch, which is isotropic, is performed to remove the remaining material of second oxide layer  52  from within gate stack  57 . The second etch is preferably an oxide etch that is carried out using nitride layer  50  as an etch stop. As such, all material in second oxide layer  52  within gate stack  57  is substantially removed, leaving only nitride layer  50 . A third etch is performed to remove the remaining material of nitride layer  50  from within gate stack  57 . The third etch is preferably an nitride etch that is carried out using gate oxide layer  12  as an etch stop. As such, all material in nitride layer  50  within gate stack  57  is substantially removed. Additional processing steps provide for patterning and etching of gate oxide layer  12  to expose regions of silicon substrate  10  to provide for source/drain contact regions  66 . Additional processing steps further provide for the implantation of dopant material into source/drain contact regions  66  of silicon substrate  10 . Implementation of said additional processing steps, however, are conventional and need not be further detailed herein. The forgoing etch process forms first and second gate tops  61  and first and second gate bottoms  63 . 
     Refractory metal layer  64 , such as titanium, is then deposited on the semiconductor wafer as shown in FIG.  3 F. In this embodiment refractory metal layer  64  is pure titanium and is deposited using chemical vapor deposition (CVD). CVD obtains a preferred coverage on the underside of first silicon layer  54  on the inside surface of silicon gate structures  60 , thereby increasing the surface area of interfacing between refractory metal layer  64  and silicon surfaces. 
     One or more high temperature annealing steps will then be performed so that the material in refractory metal layer  64  reacts with the silicon in silicon gate structures  60  and in source/drain contact regions  66  to form a polycide layer. Temperatures during the high temperature annealing steps will be in a range from about 700° C. to about 1100° C. and will vary based on other device fabrication factors. In this embodiment, titanium will be the material from which refractory metal layer  64  is composed. The temperature will be preferably sufficient to transform the titanium silicide formed from the reaction of refractory metal layer  64  with silicon gate structures  60  and so as to form the C54 crystalline phase upon both silicon gate structures  60 . 
     Material from refractory metal layer  64  that is unreacted with exposed silicon on the semiconductor wafer is then removed using an conventional etching process leaving a structure as is illustrated in FIG.  3 G. Additionally, it may be preferably to remove refractory metal silicide material from surfaces  67  on silicon gate structures  60 . 
     A first passivation layer  68  is then deposited on the semiconductor wafer as shown in FIG.  3 H. First passivation layer  68  is typically a material such as BPSG. The semiconductor wafer is then patterned with photoresist layer  70  and etched to form a contact plug region  72  as shown in FIG. 3I. A titanium/titanium nitride liner  76  is then formed on the inside surfaces of contact plug region  72 . A tungsten silicide contact plug  78  is then formed within the inside surfaces of titanium/titanium nitride liner  76  within contact plug region  72 . Seen in  3 I is a contact made by titanium/titanium nitride liner  76  with gate oxide layer  12  above source/drain region  66  which is between the two silicon gate structures  60 . A metal layer  74  is then formed, incident to a metalization process, on top of first passivation layer  68  making conductive contact with the tungsten suicide contact plug. FIG. 3I shows that first and second gate tops  61  and first and second gate bottoms  63 , in combination, have cross-sectional shapes of a “C” or inverted “C”. 
     In FIG. 4A, a first silicon layer  54  is formed on top of a gate oxide layer  12  of a silicon substrate  10  of a semiconductor wafer. Gate oxide layer  12  is typically an oxide layer grown directly on base silicon substrate material of silicon substrate  10 , although gate oxide layer  12  could also be a deposited oxide layer, and the base silicon substrate material of silicon substrate  10  could be an epitaxial silicon layer. A nitride layer  50  is formed on top of second oxide layer  54 , typically being deposited by a CVD process. In this embodiment, nitride layer  50  is preferably composed of an electrical insulator such as silica or silicon nitride, although other materials could be used. 
     A second silicon layer  55  is then formed on top of nitride layer  50 . First and second silicon layers  54 ,  55  could be either polysilicon or amorphous silicon and its composition would depend on other device and process factors. First and second silicon layers  54 ,  55  are typically deposited by a sputtering or chemical vapor deposition (CVD) processes. The thickness of first silicon layer  54  is in a range from about 800 Angstroms to about 1500 Angstroms, and is preferably about 1500 Angstroms thick. The thickness of second silicon layer  55  is in a range from about 1000 Angstroms to about 2000 Angstroms, and is preferably about 2000 Angstroms thick. 
     The semiconductor wafer is then patterned as shown in FIG. 3A with a photoresist layer  56 , and then subjected to an etching process. The result of the etching process is seen in FIG. 4B, where material from nitride layer  50 , and material from first and second silicon layers  54 ,  55  are removed. The etching process is performed so that nitride layer  50  is undercut. The undercut of nitride layer  50 , on each side thereof illustrated in FIG. 4B is preferably in a range from about 0.05 microns to about 0.1 microns, leaving the remaining illustrated length of nitride layer  50  preferably in a range from about 0.05 microns to about 0.15 microns. 
     Refractory metal layer  64 , such as titanium, is then deposited on the semiconductor wafer as shown in FIG.  4 B. In this embodiment, refractory metal layer  64  is pure titanium and is deposited using chemical vapor deposition (CVD). CVD obtains a preferred coverage on the underside of second silicon layer  55 , thereby increasing the surface area of interfacing between refractory metal layer  64  and silicon surfaces. Additionally, the undercut regions of nitride layer  50  are also coated the CVD deposited refractory metal layer  64 . 
     One or more high temperature annealing steps will then be performed so that the material in refractory metal layer  64  reacts with exposed silicon surfaces. Temperatures during the high temperature annealing steps will be in a range from about 550° C. to about 1100° C. and will vary based on other device fabrication factors. In this embodiment, titanium will be the material from which refractory metal layer  64  is composed. The temperature will be preferably sufficient to transform the titanium silicide formed from the reaction of refractory metal layer  64  with silicon surfaces so as to form the C54 crystalline phase upon the silicon surfaces. 
     Material from refractory metal layer  64  that is unreacted with exposed silicon on the semiconductor wafer is then removed using an conventional etching process leaving a structure as is illustrated in FIG.  4 B. FIG. 4B also shows nitride layer  50  has being coated at the undercut regions thereof by a refractory metal suicide of refractory metal layer  64 . Such coating is due to the creep phenomena described above. As such, refractory metal layer  64  serves as a conductive strapping between first and second silicon layers  54 ,  55 . The strapping arrangement increases the conductive surface area with a low resistivity layer on the resultant structure. 
     A third silicon layer  58  is then deposited on the semiconductor wafer as shown in FIG.  4 C. Third silicon layer  58  will preferably be deposited with a CVD process so that the aforedescribed undercut areas of nitride layer  50  are filled with third silicon layer  58 . Third silicon layer  58  must also be deposited in such a manner that spacers can be formed on either side of first and second silicon layers  54 ,  55  in a subsequent spacer etch of third silicon layer  58 . As such, third silicon layer  58  makes conductive contact with the vertical sides of first and second silicon layers  54 ,  55  so that a single complex polysilicon gate structure is formed. Source and drain regions may then be conventionally formed within silicon substrate  10 . FIG. 4C shows an “I” shape in cross-section from the combination of first and second silicon layers  54 ,  55  with nitride layer  50 . 
     FIG. 5 illustrates a top planar view of DRAM structure showing a folded bit line architecture having alternating columns of islands. Seen in FIG. 5 are field oxide regions  202 , access transistor gates  204 , storage nodes and active areas  206 , digit nodes  208 , and a contact seen in phantom at  210  at cutaway regions  212 . The wordlines see in FIG. 5 are formed according to the inventive methods disclosed herein and have both transistor gate structures and parasitic field devices. Each wordline in FIG. 5 is situated on a substrate assembly and is parallel to other wordlines thereon. By way of example, and not by way of limitation, complex gate structure  32  which includes base polysilicon region  30  and silicon riser structure  24  as shown in FIG. 1E can be depicted in top view thereof in FIG.  5 . Particularly, the widest portion of base polysilicon region  30  seen in FIG. 1F is seen as a word line width extending between  240  and  242  in FIG.  5 . Also, silicon riser structure  24  as shown in FIG. 1E can be generally depicted at  224  in FIG.  5 . As such, each wordline depicted in FIG. 5 can incorporate a structural component having a cross-sectional shape of a “C” or inverted “C” seen in FIG. 3I, or an “I” shape seen in FIG.  4 C. 
     The structures described above can be integrated into the fabrication of a variety of memory devices, including SRAM, logic memory, flash memory, and DRAM. Such integration can include both wordline gate structures and three dimensional capacitor structures, such as storage node and cell plate capacitor components. By creating the polycide DRAM wordline structures described above, or such structures integrated into the fabrication of other memory devices, where each such structure has a complex silicided gate surface, the overall resistivity of the wordline structure is optimized, as is the surface area optimized, each benefit of which contributes to an enhancement of device performance and speed. 
     The present invention may also be embodied in other specific forms without departing from its spirit or essential characteristics. The described embodiments are to be considered in all respects only as illustrated and not restrictive. The scope of the invention is, therefore, indicated by the appended claims rather than by the foregoing description. All changes which come within the meaning and range of equivalency of the claims are to be embraced within their scope.

Technology Classification (CPC): 7