Abstract:
A ferroelectric capacitor includes a bottom electrode, a top electrode, and a ferroelectric layer located between the top and bottom electrodes that extends to completely encapsulate the top electrode, except for a contact hole to allow metalization of the top electrode. The total encapsulation of the top electrode reduces the sensitivity of the ferroelectric capacitor to hydrogen and thus improves electrical switching performance. The encapsulation technique can also be used to improve the performance of ferroelectric transistors and other devices.

Description:
RELATED APPLICATIONS 
     The present application is a continuation-in-part of patent application Ser. No. 08/700,076 entitled &#34;Partially Or Completely Encapsulated Top Electrode Of A Ferroelectric Capacitor&#34;, which was filed on Aug. 20, 1996 now U.S. Pat. No. 5,920,453. 
    
    
     FIELD OF THE INVENTION 
     This invention relates generally to ferroelectric capacitors and transistors. More particularly, the present invention relates to a technique and structure for preventing degradation in the electrical performance of ferroelectric capacitors and transistors. 
     BACKGROUND OF THE INVENTION 
     A portion of a prior art integrated circuit ferroelectric memory cell 10 including a transistor and a ferroelectric capacitor is shown in FIG. 1. A silicon or other substrate 12 includes a diffused region 14, which forms part of a transistor used in the memory cell. A thick oxide layer 16 forms the substrate for the ferroelectric capacitor. The thick oxide layer 16 is patterned and etched to allow access to diffused region 14. The ferroelectric capacitor includes a platinum bottom electrode 18, a ferroelectric layer 20, typically PZT (lead zirconate titanate), and a platinum top electrode 22. A subsequent oxide layer 24 is deposited, which is patterned and etched, to provide access to diffused region 14, bottom electrode 18, and to top electrode 22. A local interconnect layer 26 is deposited, patterned and etched, to provide a local interconnect 26A between top electrode 22 and diffused region 14, as well as metalization 26B for bottom electrode 18. 
     It is well known in the ferroelectric arts that certain ferroelectric materials, particularly PZT, are susceptible to degradation of electrical switching performance if exposed to hydrogen. One source of hydrogen can be found in the plastic packaging materials often used with integrated circuits. Another source of hydrogen can be found in the various oxide layers used in fabricating the ferroelectric capacitor or memory cell. 
     A section 28 of memory cell 10 is shown in greater magnification in FIG. 2 to illustrate the problem of hydrogen sensitivity that exists within the prior art memory cell. Section 28 shows oxide layer 16, bottom electrode 18, ferroelectric layer 20, top electrode 22, oxide layer 24, and local interconnect 26A. Note particularly in FIG. 2 that there is an interface between oxide layer 24 and ferroelectric layer 20. The interface extends along the top surface and sides of ferroelectric layer 20. During and after fabrication, hydrogen is generated within oxide layer 24, which in turn is gradually absorbed by ferroelectric layer 20. The arrows shown in FIG. 2 show generally the probable path of hydrogen diffusion into the ferroelectric layer 20. Studies have shown that exposure to hydrogen gradually degrades the amount of switching charge produced by the ferroelectric capacitor. Over time, the exposure to hydrogen may destroy electrical switching performance altogether. 
     What is desired, therefore, is a technique and structure to reduce hydrogen sensitivity in an integrated ferroelectric capacitor. 
     SUMMARY OF THE INVENTION 
     It is, therefore, a principal object of the present invention to improve the electrical switching performance of integrated circuit ferroelectric capacitors and transistors by reducing sensitivity to hydrogen. 
     It is another object of the invention to improve the performance of ferroelectric memory circuits. 
     It is an advantage of the invention that the fabrication methods set forth are generally compatible with existing ferroelectric capacitor and ferroelectric memory fabrication methods. 
     It is another advantage of the invention that the capacitor fabricated as set forth herein can be used in a wide array of electronic products such as integrated circuit memories and other integrated circuits, RF/ID integrated circuits and cards, discrete devices, or any application in which improved electrical switching performance and resistance to hydrogen diffusion is desired. 
     According to a first general embodiment of the present invention, a ferroelectric capacitor includes a bottom electrode, a top electrode, and a ferroelectric layer located between the top and bottom electrodes that extends to completely encapsulate the top electrode, except for a contact hole to allow metalization of the top electrode. The total encapsulation of the top electrode reduces the sensitivity of the ferroelectric capacitor to hydrogen and thus improves electrical switching performance. 
     According to a second general embodiment of the present invention, a ferroelectric capacitor includes a bottom electrode and a ferroelectric layer formed on the bottom electrode. The ferroelectric layer is partially etched to form an indentation to receive a top electrode. A dielectric layer is formed over the ferroelectric layer, and includes a contact hole to allow metalization of the top electrode. The partial encapsulation of the top electrode also reduces the sensitivity of the ferroelectric capacitor to hydrogen. 
     The ferroelectric layer in the capacitor can be fabricated using PZT, SBT, or other known ferroelectric materials. The ferroelectric capacitor can then be used in conjunction with a transistor to form a memory cell in an array of such cells. 
     A first method of fabricating a ferroelectric capacitor according to the present invention includes the steps of: forming in sequence a bottom electrode layer, a first ferroelectric layer, and a top electrode layer; etching the top electrode layer to form a top electrode; forming a second ferroelectric layer over the first ferroelectric layer, thereby completely encapsulating the top electrode; etching the second ferroelectric layer; etching the first ferroelectric layer and the bottom electrode layer to form a bottom electrode; forming a dielectric layer over the etched first ferroelectric and second ferroelectric layers; etching a contact hole through. the dielectric layer and the second ferroelectric layer to allow metalization of the top electrode; and etching a contact hole through the dielectric layer and the first ferroelectric layer to allow metalization of the bottom electrode. 
     A second method of fabricating a ferroelectric capacitor according to the present invention includes the steps of: forming in sequence a bottom electrode layer, a first ferroelectric layer, and a top electrode layer; etching the top electrode layer to form a top electrode; etching the first ferroelectric layer; etching the bottom electrode layer to form a bottom electrode; forming a second ferroelectric layer over the first ferroelectric layer, thereby completely encapsulating the top electrode; etching the second ferroelectric layer so that the second ferroelectric layer overlaps the bottom electrode; forming a dielectric layer over the etched second ferroelectric layer; and etching contact holes through the dielectric layer and the second ferroelectric layer to allow metalization of the top and bottom electrodes. 
     A third method of fabricating a ferroelectric capacitor according to the present invention includes the steps of: forming in sequence a bottom electrode layer, a first ferroelectric layer, and a top electrode layer; etching the top electrode layer to form a top electrode; etching the first ferroelectric layer; etching the bottom electrode layer to form a bottom electrode; forming a second ferroelectric layer over the first ferroelectric layer, thereby completely encapsulating the top electrode; forming a dielectric layer over the second ferroelectric layer; and etching contact holes through the dielectric layer and the second ferroelectric layer to allow metalization of the top and bottom electrodes. 
     A fourth method of fabricating a ferroelectric capacitor according to the present invention includes the steps of: forming in sequence a bottom electrode layer, a first ferroelectric layer of a first thickness, and a top electrode layer; etching the top electrode layer to form a top electrode; etching the first ferroelectric layer; forming a second ferroelectric layer of a second thickness over the first ferroelectric layer, thereby completely encapsulating the top electrode; etching the second ferroelectric layer and the bottom electrode layer to form a bottom electrode; forming a dielectric layer over the etched second ferroelectric layer; and etching contact holes through the dielectric layer and the second ferroelectric layer to allow metalization of the top and bottom electrodes. 
     A fifth method of fabricating a ferroelectric capacitor according to the present invention includes the steps of: forming in sequence a bottom electrode layer and a ferroelectric layer; partially etching the ferroelectric layer to form an indentation; forming a conformal top electrode layer over the ferroelectric layer; etching away the top electrode layer to form a top electrode in the indentation; etching the ferroelectric layer; etching the bottom electrode layer to form a bottom electrode; forming a dielectric layer over the etched ferroelectric layer; and etching contact holes through the dielectric layer to allow metalization of the top and bottom electrodes. 
     A sixth method of fabricating a ferroelectric capacitor according to the present invention includes the steps of: forming a bottom electrode layer; etching the bottom electrode layer to form a bottom electrode; forming a ferroelectric layer over the bottom electrode; partially etching the ferroelectric layer to form an indentation; forming a conformal top electrode layer over the ferroelectric layer; etching away the top electrode layer to form a top electrode in the indentation; forming a dielectric layer over the ferroelectric layer; etching a contact hole through the dielectric layer to allow metalization of the top electrodes; and etching a contact hole through the dielectric layer and the ferroelectric layer to allow metalization of the bottom electrode. 
     An integrated circuit ferroelectric memory cell having a bit line, a word line, and a plate line, fabricated according to the present invention includes: a silicon substrate or epitaxial region; a transistor formed in the substrate including first and second diffused regions, a thin gate oxide, and a gate forming the word line; a thick oxide layer formed on the substrate including contact holes to allow metalization of the first and second diffused regions; a ferroelectric capacitor formed on the thick oxide layer, the ferroelectric capacitor including a bottom electrode, a ferroelectric layer, and a top electrode, wherein the ferroelectric layer either partially or completely encapsulates the top electrode and includes a contact hole to allow metalization of the top electrode; a first dielectric layer formed over the thick oxide layer and the ferroelectric capacitor including contact holes to allow metalization of the first and second diffused regions, and the top and bottom electrodes of the ferroelectric capacitor; a first patterned metalization layer for the top electrode and the second diffused region, and for metalizing the bottom electrode; a second dielectric layer formed over the first metalization layer including contact holes to allow metalization of the first diffused region and the bottom electrode; a second patterned metalization layer for contacting the first diffused region to form the bit line, and for contacting the bottom electrode to form the plate line; and a passivation layer formed over the second metalization layer. If desired, the first dielectric layer, the second dielectric layer, and the passivation layer can each be formed as a ferroelectric layer for an even greater resistance to hydrogen degradation. 
    
    
     The foregoing and other objects, features and advantages of the invention will become more readily apparent from the following detailed description of a preferred embodiment of the invention which proceeds with reference to the accompanying drawings. 
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a sectional view of a portion of a prior art integrated circuit ferroelectric memory including a ferroelectric capacitor and a transistor; 
     FIG. 2 is a magnified view of a prior art ferroelectric capacitor illustrating particularly the problem of hydrogen diffusion into the ferroelectric dielectric layer resulting in degradation of electrical switching performance; 
     FIGS. 3-9 are sequential sectional views of a ferroelectric capacitor process suitable for use in a ferroelectric memory having decreased hydrogen sensitivity according to a first embodiment of the invention; 
     FIG. 10 is a plan view of a set of ferroelectric capacitors fabricated according to the process shown in FIGS. 3-9; 
     FIGS. 11-17 are sequential sectional views of a ferroelectric capacitor process suitable for use in a ferroelectric memory having decreased hydrogen sensitivity according to a second embodiment of the invention; 
     FIG. 18 is a plan view of a set of ferroelectric capacitor fabricated according to the process shown in FIGS. 11-17; 
     FIGS. 19-24 are sequential sectional views of a ferroelectric capacitor process suitable for use in a ferroelectric memory having decreased hydrogen sensitivity according to a third embodiment of the invention; 
     FIG. 25 is a plan view of a set of ferroelectric capacitor fabricated according to the process shown in FIGS. 19-24; 
     FIGS. 26-32 are sequential sectional views of a ferroelectric capacitor process suitable for use in a ferroelectric memory having decreased hydrogen sensitivity according to a fourth embodiment of the invention; 
     FIGS. 33-41 are sequential sectional views of a ferroelectric capacitor process suitable for use in a ferroelectric memory having decreased hydrogen sensitivity according to a fifth embodiment of the invention; 
     FIGS. 42-50 are sequential sectional views of a ferroelectric capacitor process suitable for use in a ferroelectric memory having decreased hydrogen sensitivity according to a sixth embodiment of the invention; 
     FIG. 51 is a schematic diagram of a ferroelectric memory cell having a transistor and a ferroelectric capacitor; 
     FIG. 52 is a sectional view of a completely metalized integrated circuit ferroelectric memory, in which the top electrode of the ferroelectric capacitor is completely encapsulated according to the present invention; 
     FIGS. 53-69 are sequential sectional views that illustrate an improved fabrication method for forming a first embodiment of a ferroelectric FET including at least two source/drain regions and a ferroelectric gate structure in which the ferroelectric gate structure is encapsulated with a hydrogen-barrier cap layer distinct from the ferroelectric gate structure; 
     FIGS. 70-77 are sequential sectional views that illustrate an improved fabrication method for forming a second embodiment of a ferroelectric FET including at least two source/drain regions and a ferroelectric gate structure in which a notched ferroelectric dielectric is formed on a substrate, a gate is formed in the notch of the ferroelectric dielectric, and source/drain regions are formed in the substrate; 
     FIGS. 78-84 are sequential sectional views that illustrate an improved fabrication method for forming a third embodiment of a ferroelectric FET including at least two source/drain regions and a ferroelectric gate structure in which a first ferroelectric layer is formed over the substrate, a gate is formed on the first ferroelectric layer, a second ferroelectric layer is formed over the first ferroelectric layer and gate, the first and second ferroelectric layers are etched to define the lateral dimensions of the dielectric, and the second ferroelectric layer is etched to access the gate; and 
     FIGS. 85-89 are sequential sectional views that illustrate a method of protecting any ferroelectric device resident on an integrated circuit from hydrogen damage, the method comprising the step of encapsulating the ferroelectric device with a hydrogen-barrier cap layer distinct from the ferroelectric device. 
    
    
     DETAILED DESCRIPTION 
     Referring now to FIGS. 3-9, sequential sectional views of a first ferroelectric capacitor process suitable for use in a ferroelectric memory having decreased hydrogen sensitivity are shown. 
     In FIG. 3, a layer 16 of BPSG glass about 7000 Angstroms thick is deposited onto a silicon or other substrate (not shown). Any oxide, nitride, or other appropriate dielectric layer can be substituted for BPSG layer 16. A platinum bottom electrode layer 18 is subsequently deposited over BPSG glass layer 16 to a thickness of about 1750 Angstroms. While platinum is used for electrode layer 16, other known materials compatible with ferroelectric films can be used including iridium, iridium oxide, and the like. The bottom electrode layer 18 also includes a titanium adhesion layer about 200 Angstroms thick to facilitate the adhesion of the platinum bottom electrode layer 18 to BPSG glass layer 16. A first ferroelectric layer 20 is subsequently deposited over the bottom electrode layer 18 to a thickness of about 3000 Angstroms. The material used in ferroelectric layer 20 is ideally doped or undoped PZT (lead zirconate titanate), SBT (strontium bismuth tantalate), or any other known ferroelectric material suitable for use in thin film form. 
     After the ferroelectric layer 20 is deposited, a first anneal is performed. The first anneal includes a 650° C. heat treatment for about five seconds, followed by an 850° C. heat treatment for about five seconds. 
     A platinum top electrode layer 22 is subsequently deposited over the first ferroelectric layer 20 to a thickness of about 1750 Angstroms. The material used in top electrode layer 22 can be other than platinum as described above. Top electrode layer 22 is etched to form one or more top electrodes. Platinum is typically etched using a reactive-ion etch in an argon and chlorine atmosphere, although other gases can be used. Ion milling can be used as well as an alternative etching technique. The dimensions of the individual top electrodes can modified as desired from nominal dimensions of 1.5×1.5 microns, with a spacing of about three microns between top electrodes. After the platinum top electrode layer 20 is etched to define the individual top electrodes, a second anneal is performed. The second anneal includes a 650° C. heat treatment for about sixty minutes in an oxygen atmosphere. 
     In FIG. 4, a second &#34;cap&#34; ferroelectric layer 30 about the same thickness (3000 Angstroms) as the first ferroelectric layer 20 is deposited over the first ferroelectric layer 20, thereby completely encapsulating the top electrodes 22. The material used in the second ferroelectric layer 30 is also ideally doped or undoped PZT (lead zirconate titanate), SBT (strontium bismuth tantalate), or any other known ferroelectric material suitable for use in thin film form. The first and second ferroelectric layers need not be the same ferroelectric material, since the second layer is used for its resistance to hydrogen diffusion or hydrogen &#34;gettering&#34; properties and not specifically for its ferroelectric properties. After the second ferroelectric layer 30 is deposited, an optional third anneal can be performed. The optional third anneal includes a 650° C. heat treatment for about sixty minutes in an oxygen atmosphere. 
     In FIG. 5, the second ferroelectric layer 30 is etched according to the same etching method as set forth for the first ferroelectric layer 20. The second ferroelectric layer 30 is etched to leave a reasonable overlap of the top electrodes 22, about 1.5 to 2.0 microns. 
     In FIG. 6, the first ferroelectric layer 20 and the bottom electrode layer 18 are simultaneously etched to define the dimensions of a bottom electrode. As can be seen in FIG. 6, one end of the bottom electrode 18 is etched to allow sufficient room for an eventual bottom electrode contact. The other end of bottom electrode 18 is etched to the same dimensions as the second ferroelectric layer 30. The first ferroelectric layer 20 and the bottom electrode layer 18 are simultaneously etched using a reactive-ion etch in an argon and carbon tetrafluoride atmosphere, although other gases can be used. Ion milling can also be used as an alternative etching technique. After the first ferroelectric layer 20 and bottom electrode layer 18 are etched, an optional first recovery anneal can be performed. The optional first recovery anneal includes a 550° C. heat treatment for about sixty minutes in an oxygen atmosphere. 
     In FIG. 7, a PTEOS glass dielectric layer 24 is deposited over the etched first ferroelectric and second ferroelectric layers 20 and 30 to a thickness of about 5000 Angstroms. Other dielectic layers can be used for dielectric layer 24. 
     In FIG. 8, contact holes are etched to provide access of the top and bottom electrodes 22 and 18. Contact hole 32 provides access to bottom electrode 18, and contact holes 34 provide access to top electrodes 22. Contact holes 34 are etched through the dielectric layer 24 and the second ferroelectric layer 30 to allow metalization of the top electrodes. Contact hole 32 is etched through the dielectric layer 24 and the first ferroelectric layer 20 to allow metalization of bottom electrode 18. Note that the contact holes 32 and 34 are ideally etched in two steps. The first etching step removes the dielectric layer 24 in the contact holes. The dielectric oxide material can be etched away using a fluorine-based wet or dry etch. It is desirable that a sloped profile is etched into the contact holes. After the dielectric oxide material is removed, the remaining ferroelectric material in the contact hole is etched away according to the ferroelectric etch described above. Note in FIG. 8 that contact holes 32 and 34 are etched through about the same thickness of material, i.e. 5000 Angstroms of glass plus 3000 Angstroms of ferroelectric material. Therefore, the etching of contact holes 32 and 34 can be performed simultaneously. After contact holes 32 and 34 are etched, an optional second recovery anneal can be performed. The optional second recovery anneal includes a 550° C. heat treatment for about sixty minutes in an oxygen atmosphere. 
     In FIG. 9, contact holes 32 and 34 are metalized to provide electrical access to bottom electrode 18 and top electrodes 22. A titanium nitride local interconnect metalization layer is deposited to a thickness of about 800 Angstroms and etched to form a metal contact 36 for bottom electrode 18 and a metal contact 38 for each of the top electrodes 22. The full metalization scheme showing subsequent oxide and metalization layers for a ferroelectric memory cell is shown in FIG. 52, although other metalization schemes can be used. For example, a titanium layer about 1500 Angstroms thick followed by an aluminum layer of about 8000 Angstroms thick can be used to form metal contacts 36 and 38. Other metalization techniques can be used as well after the titanium nitride layer has been deposited. 
     A plan view of the capacitor structure described above with respect to FIGS. 3-9 is shown in FIG. 10. The bottom electrode 18 and first ferroelectric layer 20 are shown as coincident layers forming a first rectangle. A second, smaller rectangle is formed of the bottom electrode 18, the first ferroelectric layer 20, and the second ferroelectric layer 30. The contact holes to the bottom and top electrodes 32 and 34 are shown as circular features. The local interconnect metal contact straps 38 that contact the top electrodes 22 are shown as individual rectangles overlapping contact holes 34 and 40. Contact holes 40 are not shown in FIGS. 3-9 but represent a contact to another structure such as the diffused region of a transistor as is shown in FIG. 52. 
     Referring now to FIGS. 11-17, sequential sectional views of a second ferroelectric capacitor process suitable for use in a ferroelectric memory having decreased hydrogen sensitivity are shown. 
     FIG. 11 is the same sectional view as FIG. 3, showing the sequential deposition of a thick glass layer 16, a bottom electrode layer 18, a first ferroelectric layer 20, and a top electrode layer 22. All of the thicknesses and materials described above are the same in FIG. 11. A first anneal can be performed after the first ferroelectric layer 18 is deposited. The platinum top electrode layer 22 is etched to form individual top electrodes 22. A second anneal can be performed after the top electrodes 22 are etched. 
     In FIG. 12, the first ferroelectric layer 20 is etched with some lateral overlap of the etched top electrodes 20. The bottom electrode layer 18 is etched to define the dimensions of a bottom electrode. As can be seen in FIG. 12, one end of the bottom electrode 18 is etched to allow sufficient room for the eventual bottom electrode contact. The other end of bottom electrode 18 is etched to the same dimensions as the first ferroelectric layer 20. The etching techniques for bottom electrode 18 and first ferroelectric layer 20 are as described above with reference to FIGS. 3-11. After the first ferroelectric layer 20 and bottom electrode layer 18 are etched, an optional first recovery anneal can be performed. The optional first recovery anneal includes a 550° C. heat treatment for about sixty minutes in an oxygen atmosphere. 
     In FIG. 13, a second &#34;cap&#34; ferroelectric layer 30 about the same thickness (3000 Angstroms) as the first ferroelectric layer 20 is deposited over the first ferroelectric layer 20, thereby completely encapsulating the top electrodes 22. After the second ferroelectric layer 30 is deposited, an optional third anneal can be performed. The optional third anneal includes a 650° C. heat treatment for about sixty minutes in an oxygen atmosphere. 
     In FIG. 14, the second ferroelectric layer 30 is etched according to the same etching method as set forth for the first ferroelectric layer 20. The second ferroelectric layer 30 is etched to leave a reasonable overlap of the bottom electrode 18, about 1.5 to 2.0 microns. After the second ferroelectric layer 30 is etched, an optional second recovery anneal can be performed. 
     In FIG. 15, a PTEOS glass dielectric layer 24 is deposited over the etched second ferroelectric layers 30 to a thickness of about 5000 Angstroms. 
     In FIG. 16, contact holes are etched to provide access of the top and bottom electrodes 22 and 18. Contact hole 32 provides access to bottom electrode 18, and contact holes 34 provide access to top electrodes 22. Note that in FIG. 16, both contact holes 34 and 36 are etched through the dielectric layer 24 and the second ferroelectric layer 30 to allow metalization of the top and bottom electrodes. The thickness of contact holes 34 and 36 is the same since they are etched through the same thickness of material. Contact holes 32 and 34 are ideally simultaneously etched in two steps to remove the dielectric oxide material and then the remaining ferroelectric material. The type of etch used in the same as described with reference to FIG. 8. After contact holes 32 and 34 are etched, an optional second recovery anneal can be performed. 
     In FIG. 17, contact holes 32 and 34 are metalized to provide electrical access to bottom electrode 18 and top electrodes 22. A titanium nitride local interconnect metalization layer is deposited to a thickness of about 800 Angstroms and etched to form a metal contact 36 for bottom electrode 18 and a metal contact 38 for each of the top electrodes 22. The full metalization scheme showing subsequent oxide and metalization layers for a ferroelectric memory cell is shown in FIG. 52, although other metalization schemes can be used. 
     A plan view of the capacitor structure described above with respect to FIGS. 11-17 is shown in FIG. 18. The bottom electrode 18 is shown as forming a first rectangle. A second, smaller rectangle is formed of the bottom electrode 18 and the first ferroelectric layer 20. The second ferroelectric layer 30 is shown as a dashed rectangle overlapping the bottom electrode 18. The contact holes to the bottom and top electrodes 32 and 34 are shown as circular features. The local interconnect metal contact straps 38 that contact the top electrodes 22 are shown as individual rectangles overlapping contact holes 34 and 40. Contact holes 40 are not shown in FIGS. 11-17 but represent a contact to another structure such as the diffused region of a transistor as is shown in FIG. 52. 
     Referring now to FIGS. 19-24, sequential sectional views of a third ferroelectric capacitor process suitable for use in a ferroelectric memory having decreased hydrogen sensitivity are shown. 
     FIGS. 19-21 are identical to previously described FIGS. 11-13 both in sectional views, material, etching, and annealing steps. FIG. 19 shows a thick glass layer 16, a bottom electrode layer 18, a first ferroelectric layer 20, and a top electrode layer 22 formed in sequence, wherein the top electrode layer 22 is etched to form individual top electrodes 22. FIG. 20 shows the etching of the first ferroelectric layer 20 and the etching of the bottom electrode layer 18 to form a bottom electrode. In FIG. 21, a second &#34;cap&#34; ferroelectric layer 30 about the same thickness (3000 Angstroms) as the first ferroelectric layer 20 is deposited over the first ferroelectric layer 20, thereby completely encapsulating the top electrodes 22. A first anneal is performed after the ferroelectric layer 20 is deposited, a second anneal is performed after the top electrode layer 22 is etched, and an optional third anneal is performed after the second ferroelectric layer 30 is deposited. A optional first recovery anneal is performed after the first ferroelectric layer 20 and bottom electrode layer 18 have been etched. 
     In FIG. 22, a PTEOS glass dielectric layer 24 is deposited over the unetched second ferroelectric layer 30 to a thickness of about 5000 Angstroms. 
     In FIG. 23, contact holes are etched to provide access of the top and bottom electrodes 22 and 18. Contact hole 32 provides access to bottom electrode 18, and contact holes 34 provide access to top electrodes 22. Note that in FIG. 23, both contact holes 34 and 36 are etched through the dielectric layer 24 and the second ferroelectric layer 30 to allow metalization of the top and bottom electrodes. The thickness of contact holes 34 and 36 is the same since they are etched through the same thickness of material. Contact holes 32 and 34 are ideally simultaneously etched in two steps to remove the dielectric oxide material and then the remaining ferroelectric material. The type of etch used in the same as described with reference to FIG. 8. A second optional recovery anneal can be performed after contact holes 32 and 34 have been opened. 
     In FIG. 24, contact holes 32 and 34 are metalized to provide electrical access to bottom electrode 18 and top electrodes 22. A titanium nitride local interconnect metalization layer is deposited to a thickness of about 800 Angstroms and etched to form a metal contact 36 for bottom electrode 18 and a metal contact 38 for each of the top electrodes 22. The full metalization scheme showing subsequent oxide and metalization layers for a ferroelectric memory cell is shown in FIG. 52, although other metalization schemes can be used. 
     A plan view of the capacitor structure described above with respect to FIGS. 19-24 is shown in FIG. 25. The bottom electrode 18 is shown as forming a first rectangle. A second, smaller rectangle is formed of the bottom electrode 18 and the first ferroelectric layer 20. The second ferroelectric layer 30 is shown as a dashed rectangle overlapping the bottom electrode 18 by a wide margin. The wide margin shown is meant to convey the unetched, continuous extent of the second ferroelectric layer 30. The contact holes to the bottom and top electrodes 32 and 34 are shown as circular features. The local interconnect metal contact straps 38 that contact the top electrodes 22 are shown as individual rectangles overlapping contact holes 34 and 40. Contact holes 40 are not shown in FIGS. 19-24 but represent a contact to another structure such as the diffused region of a transistor as is shown in FIG. 52. 
     Referring now to FIGS. 26-32, sequential sectional views of a fourth ferroelectric capacitor process suitable for use in a ferroelectric memory having decreased hydrogen sensitivity are shown. The fourth ferroelectric capacitor process described below allows the thickness of the second ferroelectric layer 30 to be different from the first ferroelectric layer 20, if desired. 
     FIG. 26 is the same as previously described FIGS. 3, 11, and 19. A first anneal is performed after the first ferroelectric layer 20 is deposited, and a second anneal is performed after the top electrode layer 22 is etched. 
     In FIG. 27, only the first ferroelectric layer 20 is etched to a reasonable overlap of the etched top electrodes 22. The bottom electrode layer 18 remains unetched in FIG. 27. An optional first recovery anneal is performed after the first ferroelectric layer 20 is etched. 
     In FIG. 28, a second &#34;cap&#34; ferroelectric layer 30&#39; of a different thickness (less than or greater than 3000 Angstroms) from the first ferroelectric layer 20 is deposited over the first ferroelectric layer 20, thereby completely encapsulating the top electrodes 22. A less thick second ferroelectric layer 30&#39; is desirable since less material is used, it is easier to etch, more planar, and for other processing reasons. However, if desired, the same or a thicker ferroelectric layer 30&#39; can be used. The material used for the second ferroelectric layer 30&#39; is the same as described above, and can be different than the material used in the first ferroelectric layer 20. An optional third anneal can be performed after the second ferroelectric layer 30&#39; is deposited. 
     In FIG. 29, the second ferroelectric layer 30&#39; and the bottom electrode layer 18 are simultaneously etched to form a bottom electrode. After the bottom electrode layer 18 and second ferroelectric layer 30&#39; have been etched, an optional second recovery anneal can be performed. 
     In FIG. 30, a PTEOS glass dielectric layer 24 is deposited over the etched second ferroelectric layer 30&#39; to a thickness of about 5000 Angstroms. 
     In FIG. 31, contact holes are etched to provide access of the top and bottom electrodes 22 and 18. Contact hole 32 provides access to bottom electrode 18, and contact holes 34 provide access to top electrodes 22. Note that in FIG. 31, both contact holes 34 and 36 are etched through the dielectric layer 24 and the second ferroelectric layer 30&#39; to allow metalization of the top and bottom electrodes. The thickness of contact holes 34 and 36 is the same since they are etched through the same thickness of material. Contact holes 32 and 34 are ideally simultaneously etched in two steps to remove the dielectric oxide material and then the remaining ferroelectric material. The type of etch used in the same as described with reference to FIG. 8. After contact holes 32 and 34 have been etched, an optional third recovery anneal can be performed. 
     In FIG. 32, contact holes 32 and 34 are metalized to provide electrical access to bottom electrode 18 and top electrodes 22. The full metalization scheme showing subsequent oxide and metalization layers for a ferroelectric memory cell is shown in FIG. 52, although other metalization schemes can be used. 
     A plan view of the capacitor structure described above with respect to FIGS. 26-32 is not shown, but is similar to the plan view shown in FIG. 18. The one difference is that the second ferroelectric layer 30&#39; does not overlap the bottom electrode 18, but is coincident thereto. 
     Referring now to FIGS. 33-41, sequential sectional views of a fifth ferroelectric capacitor process suitable for use in a ferroelectric memory having decreased hydrogen sensitivity are shown. 
     In FIG. 33, a layer 16 of BPSG glass about 7000 Angstroms thick is deposited onto a silicon or other substrate (not shown). A platinum bottom electrode layer 18 is subsequently deposited over BPSG glass layer 16 to a thickness of about 1750 Angstroms. The bottom electrode layer 18 also includes a titanium adhesion layer about 200 Angstroms thick to facilitate the adhesion of the platinum bottom electrode layer 18 to BPSG glass layer 16. A ferroelectric layer 20 is subsequently deposited over the bottom electrode layer 18 to a thickness of about 3000 Angstroms. The material used in ferroelectric layer 20 is ideally doped or undoped PZT (lead zirconate titanate), SBT (strontium bismuth tantalate), or any other known ferroelectric material suitable for use in thin film form. 
     In FIG. 34 the ferroelectric layer 20 is partially etched to form one or more indentations 42. Indentations 42 should be etched to a sufficient depth to completely receive the top electrodes as is explained in further detail below. The etching technique used is the same reactive-ion etch used in etching the ferroelectric layers. After the ferroelectric layer 20 is partially etched, a first anneal is performed. The first anneal includes a 650° C. heat treatment for about five seconds, followed by an 850° C. heat treatment for about five seconds. 
     In FIG. 35, a platinum top electrode layer 22 is subsequently deposited over the ferroelectric layer 20 to a thickness of about 1750 Angstroms. The top electrode layer 22 is conformal and thus fills in each of the indentations 42. 
     In FIG. 36, the top electrode layer 22 is etched away to form one or more top electrodes in indentations 42. Platinum is typically etched using a reactive-ion etch in an argon and chlorine atmosphere. Alternative etching techniques include ion milling or chemical mechanical polishing (CMP). The dimensions of the individual top electrodes can modified as desired from nominal dimensions of 1.5×1.5 microns, with a spacing of about three microns between top electrodes. After the platinum top electrode layer 20 is etched to define the individual top electrodes, a second anneal is performed. The second anneal includes a 650° C. heat treatment for about sixty minutes in an oxygen atmosphere. 
     In FIG. 37, the ferroelectric layer 20 is etched to leave a reasonable lateral overlap of the top electrodes 22. 
     In FIG. 38, the bottom electrode layer 18 is etched to define the dimensions of a bottom electrode. As can be seen in FIG. 38, one end of the bottom electrode 18 is etched to allow room for an eventual bottom electrode contact. The other end of bottom electrode 18 is etched to the same dimensions as the second ferroelectric layer 30. The bottom electrode layer 18 is etched using a reactive-ion etch in an argon and chlorine atmosphere. After the bottom electrode layer 18 is etched, an optional first recovery anneal can be performed. The optional first recovery anneal includes a 550° C. heat treatment for about sixty minutes in an oxygen atmosphere. 
     In FIG. 39, a PTEOS glass dielectric layer 24 is deposited over the etched ferroelectric layer 20 to a thickness of about 5000 Angstroms. 
     In FIG. 40, contact holes are etched to provide access of the top and bottom electrodes 22 and 18. Contact hole 32 provides access to bottom electrode 18, and contact holes 34 provide access to top electrodes 22. Contact holes 34 and 32 are etched through the dielectric layer 24 to allow metalization of the top electrodes and bottom electrodes 22 and 18. Note that the contact holes 32 and 34 are etched in a single etching step. The dielectric oxide material can be etched away using a fluorine-based wet or dry etch. It is desirable that a sloped profile is etched into the contact holes. Note in FIG. 40 that contact holes 32 and 34 are etched through about the same thickness of material, i.e. 5000 Angstroms of glass dielectric layer 24. A second optional recovery anneal can be performed after contact holes 32 and 34 are opened as previously described. 
     In FIG. 41, contact holes 32 and 34 are metalized to provide electrical access to bottom electrode 18 and top electrodes 22 as previously described above. 
     A plan view of the capacitor structure described above with respect to FIGS. 33-41 is similar to that shown in FIG. 10. The only difference is that there is no second level of ferroelectric material 30. The contours of the plan view, however, are the same. 
     Referring now to FIGS. 42-50, sequential sectional views of a sixth ferroelectric capacitor process suitable for use in a ferroelectric memory having decreased hydrogen sensitivity are shown. 
     In FIG. 42, a layer 16 of BPSG glass about 7000 Angstroms thick is deposited onto a silicon or other substrate (not shown). A platinum bottom electrode layer 18 is subsequently deposited over BPSG glass layer 16 to a thickness of about 1750 Angstroms. The bottom electrode layer 18 also includes a titanium adhesion layer about 200 Angstroms thick to facilitate the adhesion of the platinum bottom electrode layer 18 to BPSG glass layer 16. 
     In FIG. 43, bottom electrode layer 18 is etched to form a bottom electrode. 
     In FIG. 44, A ferroelectric layer 20 is subsequently deposited over the bottom electrode 18 to a thickness of about 3000 Angstroms. The material used in ferroelectric layer 20 is ideally doped or undoped PZT (lead zirconate titanate), SBT (strontium bismuth tantalate), or any other known ferroelectric material suitable for use in thin film form. 
     In FIG. 45 the ferroelectric layer 20 is partially etched to form one or more indentations 42. Indentations 42 should be etched to a sufficient depth to completely receive the top electrodes as is explained in further detail below. The etching technique used is the same reactive-ion etch used in etching the ferroelectric layers. After the ferroelectric layer 20 is partially etched, a first anneal is performed. The first anneal includes a 650° C. heat treatment for about five seconds, followed by an 850° C. heat treatment for about five seconds. 
     In FIG. 46, a platinum top electrode layer 22 is subsequently deposited over the ferroelectric layer 20 to a thickness of about 1750 Angstroms. The top electrode layer 22 is conformal and thus fills in each of the indentations 42. 
     In FIG. 47, the top electrode layer 22 is etched away to form one or more top electrodes in indentations 42. Platinum is typically etched using a reactive-ion etch in an argon and chlorine atmosphere. The dimensions of the individual top electrodes can modified as desired from nominal dimensions of 1.5×1.5 microns, with a spacing of about three microns between top electrodes. After the platinum top electrode layer 20 is etched to define the individual top electrodes, a second anneal is performed. The second anneal includes a 650° C. heat treatment for about sixty minutes in an oxygen atmosphere. 
     In FIG. 48, a PTEOS glass dielectric layer 24 is deposited over the etched ferroelectric layer 20 to a thickness of about 5000 Angstroms. 
     In FIG. 49, contact holes are etched to provide access of the top and bottom electrodes 22 and 18. Contact hole 32 provides access to bottom electrode 18, and contact holes 34 provide access to top electrodes 22. Contact holes 34 are etched through the dielectric layer 24 to allow metalization of the top electrodes 22. Contact hole 32, however is etched through dielectric layer 24 as well as ferroelectric layer 20. Note, therefore, that contact holes 32 and 34 are etched in two separate etching steps. The dielectric oxide material can be etched away using a fluorine-based wet or dry etch. The ferroelectric material is etched used a reactive-ion etch. It is desirable that a sloped profile is etched into the contact holes. An optional recovery anneal can be performed at this point in the process. 
     In FIG. 50, contact holes 32 and 34 are metalized to provide electrical access to bottom electrode 18 and top electrodes 22 as previously described above. 
     A plan view of the capacitor structure described above with respect to FIGS. 42-50 is similar to that shown in FIG. 25. The differences are that there is no second level of ferroelectric material 30, and the contour for ferroelectric material 20 should be removed. 
     Referring now to FIG. 51, a schematic diagram for a typical non-volatile ferroelectric memory is shown having a transistor 52 coupled to a ferroelectric capacitor 54. The configuration in FIG. 51 is known as a one-transistor, onecapacitor ferroelectric memory cell or &#34;1T/1C&#34; cell. One current node of the transistor 52 forms the bit line of the cell, and is designated 14, 46, 48 to correspond to regions in the integrated cell shown below in FIG. 52. The other current node of transistor 52 is coupled to ferroelectric capacitor 54 at node 56. The gate 15 of transistor 52 forms the word line of the memory cell. One end of capacitor 54 is coupled to transistor 52 at node 56, and the other end of capacitor 54 forms the plate line of the memory cell. The plate line node is designated 18, 36, 48 to correspond to regions in the integrated cell shown below in FIG. 52. 
     Referring now to FIG. 52, a sectional view of a completely metalized integrated circuit ferroelectric memory cell having a bit line, a word line, and a plate line is shown. The memory cell includes a silicon substrate or epitaxial region 12, and a transistor formed in the substrate 12 including first and second diffused regions 14, a thin gate oxide 13, and a gate 15 forming the word line. A thick oxide layer 16 is formed on the substrate 12 including contact holes to allow metalization of the first and second diffused regions 14. Note that in FIG. 52, the exact sequence for forming each of the various layers and contact holes within each layer is not fully described; the contact holes may actually be formed at a subsequent processing step. A ferroelectric capacitor is subsequently formed on the thick oxide layer 16, including a bottom electrode 18, a ferroelectric layer 20+30, and a top electrode 22, wherein the ferroelectric layer 20+30 either partially or completely encapsulates the top electrode 22. The ferroelectric layer 20+30 includes a contact hole to allow metalization of the top electrode 22. 
     A first dielectric layer 24 is formed over the thick oxide layer 16 and the ferroelectric capacitor, including contact holes to allow metalization of the first and second diffused regions 14, and the top and bottom electrodes 22 and 18 of the ferroelectric capacitor. A first patterned metalization layer 36, 38, 46 is deposited for contacting the first diffused region 14 with metal contact 46, for forming a local interconnect 38 between the top electrode 22 and the second diffused region 14, and for metalizing the bottom electrode 36 with metal contact 36. 
     A second dielectric layer 44 is formed over the first metalization layer 36, 38, 46 including contact holes to allow metalization of the first diffused region 14 and the bottom electrode 36. A second patterned metalization layer 48 contacts the first diffused region 14 and forms the bit line of the memory cell, and contacts the bottom electrode 18 to form the plate line of the memory cell. Finally, a passivation layer 50 is formed over the second metalization layer 48. 
     Although the first and second dielectric layers 24 and 44 are typically thin doped or undoped oxide layers, if greater resistance to hydrogen diffusion is required these layers can also be made of ferroelectric materials such as PZT or SBT. Still further, the passivation layer 50, while typically formed of silicon nitride or the like, can also be made from ferroelectric materials such as PZT or SBT. All three layers mentioned above can be fabricated of the same or different ferroelectric materials as desired, and not necessarily the same material as used in the ferroelectric layer of the ferroelectric capacitor. Further teachings regarding ferroelectric material passivation can be found in U.S. Pat. No. 5,438,023 entitled &#34;Passivation Method and Structure for a Ferroelectric Integrated Circuit using Hard Ceramic Materials or the Like&#34;, which is assigned to the assignee of the present invention, Ramtron International Corporation. While extra care can be taken to even further reduce sensitivity to hydrogen, these steps may increase fabrication costs and complexity. 
     Ferroelectric Field-effect Transistor (&#34;FET&#34;) 
     Ferroelectric FETs, sometimes referred to as &#34;MFSFETs&#34;, which stands for &#34;Metal-Ferroelectric-Semiconductor Field-Effect Transistors&#34;, have been proposed as a memory element for a ferroelectric memory device. The ferroelectric FET is similar to a standard MOSFET, with the exception that the silicon dioxide gate dielectric layer is replaced with a ferroelectric gate dielectric layer. It is postulated that the ferroelectric FET could be an alternative to 1T-2C or 2T-2C memory cells in which separate switching devices and ferroelectric capacitors are used. 
     In operation, polarization of the ferroelectric gate dielectric layer induces either accumulation or depletion/inversion of the channel underneath the gate region. Therefore, the ferroelectric FET is either off or on depending upon the ferroelectric polarization state and can thus be used as a memory element. 
     Ferroelectric FETs are deemed to be a good alternative to standard ferroelectric memory cells since the read/write mechanism is nondestructive and the cell size of a single ferroelectric FET is small. To date, however, the problems inherent in the processing of ferroelectric FETs has prevented their widespread adoption. One problem with ferroelectric FETs is interdiffusion at the interface between the ferroelectric gate dielectric layer and the semiconductor layer where the channel is formed during deposition and/or during subsequent anneal cycles. Another problem of ferroelectric FETs is the degradation of the ferroelectric gate dielectric layer during subsequent processing steps. Once interdiffusion takes place a combination of two series capacitors is actually formed. A first capacitor is ferroelectric, but the second capacitor is non-ferroelectric and actually absorbs most of the applied external voltage. This results in a marked reduction in electrical performance and cannot be cured by subsequent thermal annealing. 
     FIGS. 53-69 illustrate an improved fabrication method for forming a first embodiment of a ferroelectric FET including at least two source/drain regions and a ferroelectric gate structure in which the ferroelectric gate structure is encapsulated with a hydrogen-barrier cap layer distinct from the ferroelectric gate structure. The hydrogen-barrier cap layer both prevents degradation from hydrogen due to subsequent processing steps and minimizes or eliminates the need for subsequent recovery anneals. As a consequence, interdiffusion between the ferroelectric gate layer and the semiconductor region is also minimized. 
     Referring now to FIG. 53 a silicon or other semiconductor substrate or epitaxial layer 100 is shown in which the source/drain regions for the ferroelectric transistors are formed. 
     In FIG. 54, diffused regions such as an N-well 102 and P-well 104 are diffused into the semiconductor substrate 100. 
     In FIG. 55, field-oxide regions 106, 108, and 110 are thermally grown to a thickness of about 1 μm to electrically isolate wells 102 and 104. 
     In FIG. 56, three layers are formed. A ferroelectric gate dielectric layer 112 is formed to a thickness of about 500 to 5000 Angstroms. The ferroelectric layer 112 can be formed of any well known ferroelectric composition such as doped or undoped PZT (lead zirconate titanate), SBT (strontium bismuth titanate), BST (barium strontium titanate), or the like. Next, a polysilicon gate layer 114 is formed to a thickness of about 500 to 5000 Angstroms. Finally, a &#34;hard mask&#34; silicon dioxide layer 116 is formed at a nominal thickness of about 3000 Angstroms. 
     In FIG. 57, the surface of layer 116 is patterned, and layers 112, 114, and 116 are etched using the combination of a wet and reactive-ion etch (&#34;RIE&#34;). After the etch step is completed, the gate structure 112A and 114A, together with the remnant of the hard mask layer 116A is formed for a first P-channel ferroelectric FET. The gate structure 112B and 114B, together with the remnant of the hard mask layer 116B is also formed for a second N-channel ferroelectric FET. Note in FIG. 57 that the ferroelectric gate structure including ferroelectric dielectric layers 112A and 112B and polysilicon gates 114A and 114B are formed directly on silicon substrate 100, which will include the source/drain regions. 
     In FIG. 58, the source/drain regions of appropriate polarity for the transistors are implanted, masked by oxide regions 106, 108, and 110, and hard mask layers 116A and 116B. Source/drain regions 118A and 118B are ideally heavily P-doped to form a P-channel ferroelectric FET, whereas source/drain regions 120A and 120B are ideally heavily N-doped to form an N-channel ferroelectric FET. 
     In FIG. 59, the remnants 116A and 116B of the hard mask layer 116 are removed by etching. 
     In FIG. 60 a cap layer 122 is deposited over the entire surface of the ferroelectric transistors including the source/drain and oxide regions to a thickness of about 500 to 5000 Angstroms. The material used for the cap layer 122 can be a standard ferroelectric material as referred to above for the ferroelectric gate dielectric layer 112, i.e. doped or undoped PZT, SBT, BST, or other known ferroelectric material. In addition, cap layer 122 can be a ferroelectric or non-ferroelectric ceramic material selected from a group consisting of doped and undoped nitrides, titanates, zirconates, niobates, tantalates, stanates, hafnates, and manganates. 
     In FIG. 61 cap layer 122 is RIE etched over the source/drain regions to form encapsulating layers 122A and 122B. Note that layers 122A and 122B completely encapsulate the ferroelectric gate structures of the respective ferroelectric FETs. 
     In FIG. 62 a thin silicon oxi-nitride layer 124 is formed over the encapsulated ferroelectric FETs to a nominal thickness of about 2000 Angstroms. 
     In FIG. 63 a thick oxide layer 126 is formed over layer 124 to a thickness of about 4000 to 5000 Angstroms. 
     In FIG. 64 the thick oxide layer 126 is planarized to form planarized oxide layer 126&#39;. 
     For purposes of clarity in showing subsequent metalization steps, FIG. 65 shows an expanded view of the left half of FIG. 64, i.e. the P-channel ferroelectric transistor formed in N-well 102. 
     In FIG. 66 vias 128 and 132 are formed through the planarized oxide layer 126&#39; and the thin oxi-nitride layer 124 to provide access to the source/drain regions 118A and 118B. A via 130 is also formed through the planarized oxide layer 126&#39;, the thin oxi-nitride layer 124, and the cap layer to provide access to the ferroelectric gate structure, including gate 114A. 
     A method of metalizing the source/drain regions 118A and 118B as well as the gate 114A is shown in FIGS. 67-69. In FIG. 67, a tungsten layer 134 is formed of sufficient thickness to completely fill vias 128, 130, and 132 shown in FIG. 66. In FIG. 68, the tungsten layer 134 is etched away to the surface of the planarized oxide layer 126&#39; to form tungsten plugs 134A, 134B, and 134C. Tungsten plugs 134A and 134C provide electrical contact to the source/drain regions, and tungsten plug 134B provides electric contact to gate 114A. In FIG. 69 a conventional alumiunum or other metal layer 136 (not shown) is patterned and etched to form metal regions 136A, 136B, and 136C that are in electrical contact with tungsten plugs 134A, 134B, and 134C, respectively. 
     FIGS. 70-77 illustrate an improved fabrication method for forming a second embodiment of a ferroelectric FET including at least two source/drain regions and a ferroelectric gate structure in which a notched ferroelectric dielectric is formed on a substrate, a gate is formed in the notch of the ferroelectric dielectric, and source/drain regions are formed in the substrate. 
     Referring now to FIG. 70, a portion of a partially-fabricated ferroelectric FET is shown including silicon or other semiconductor substrate 100, N-well or P-well 102, thick field oxide layers 106 and 108, and a ferroelectric layer 112 formed to a thickness of about 200 to 5000 Angstroms. Ferroelectric layer 112 can be any ferroelectric material as described in detail above. 
     In FIG. 71, the result of two etching steps is shown. A first etching step etches ferroelectric layer 112 to form the lateral dimension of the ferroelectric dielectric layer used in the gate structure of the ferroelectric FET. A second etching step etches the upper surface of the ferroelectric dielectric 112 to form a notch 111. The ferroelectric dielectric region 112 underneath the notch 111 is etched to a thickness of about 50 to 2000 Angstroms, depending upon the initial thickness of ferroelectric layer 112. 
     In FIG. 72, a gate layer 133 is formed over the partially formed transistor. Gate layer 133 can be polysilicon, platinum, iridium, or any other suitable electrode material. Gate layer 133 is deposited to a thickness of about 300 to 5000 Angstroms, sufficient to fill notch 111. 
     In FIG. 73, gate layer 133 is completely etched away to form a gate 133. Note that gate 133 fills former notch 111 and is completely surrounded on three sides by the ferroelectric dielectric layer 112. Note also that the active portion of the gate dielectric immediately below gate 133 is completely surrounded and thus protected from hydrogen exposure and corresponding degradation in electrical performance. 
     In FIG. 74, source/drain regions 118A and 118B of appropriate polarity are formed. 
     In FIG. 75, an oxide layer 126 is formed and planarized. 
     In FIG. 76, vias are etched into oxide layer 126. Vias 128 and 132 provide access to source/drain regions 118A and 118B, and via 130 provides access to gate 133. 
     In FIG. 77, a tungsten layer 134 (not shown) has been formed and etched to create tungsten plugs 134A, 134B, and 134C, which are in electrical contact with source/drain region 118A, gate 133, and source/drain region 118B, respectively. Also shown in FIG. 77 are etched aluminum or other metal regions 136A, 136B, and 136C that are in electrical contact with tungsten plugs 134A, 134B, and 134C, respectively. 
     FIGS. 78-84 illustrate an improved fabrication method for forming a third embodiment of a ferroelectric FET including at least two source/drain regions and a ferroelectric gate structure in which a first ferroelectric layer is formed over the substrate, a gate is formed on the first ferroelectric layer, a second ferroelectric layer is formed over the first ferroelectric layer and gate, the first and second ferroelectric layers are etched to define the lateral dimensions of the dielectric, and the second ferroelectric layer is etched to access the gate. 
     Referring now to FIG. 78, a portion of a partially-fabricated ferroelectric FET is shown including silicon or other semiconductor substrate 100, N-well or P-well 102, thick field oxide layers 106 and 108, and a ferroelectric layer 112 formed to a thickness of about 50 to 2000 Angstroms thick. Ferroelectric layer 112 can be any ferroelectric material as described in detail above. 
     In FIG. 79, a gate layer is etched to form gate 133 as shown sized slightly less than the lateral dimension of the ferroelectric dielectric layer used in the gate structure of the ferroelectric FET. The thickness and material for gate 133 is as described in detail above. 
     In FIG. 80, a cap layer 113 is formed over gate 133 and the first ferroelectric layer 112. The cap layer 113 can be any doped or undoped ferroelectric material such as PZT, SBT, and BST, or other known ferroelectric materials. In addition, the cap layer 113 can be a ceramic material selected from a group consisting of doped and undoped nitrides, titanates, zirconates, niobates, tantalates, stanates, hafnates, and manganates, and can be either ferroelectric or non-ferroelectric. 
     In FIG. 81, layers 112 and 113 are etched to define the lateral dimensions of the ferroelectric gate structure, and to surround gate 133 on three sides. Note also that the active portion of ferroelectric dielectric layer 112 is completely surrounded and thus protected from hydrogen degradation. Also shown in FIG. 74 is the formation of the source/drain regions 118A and 118B. 
     In FIG. 82, an oxide layer 126 is formed and planarized. 
     In FIG. 83, vias are etched into oxide layer 126. Vias 128 and 132 provide access to source/drain regions 118A and 118B, and via 130 provides access to gate 133. 
     In FIG. 84, a tungsten layer 134 (not shown) has been formed and etched to create tungsten plugs 134A, 134B, and 134C, which are in electrical contact with source/drain region 118A, gate 133, and source/drain region 118B, respectively. Also shown in FIG. 84 are etched aluminum or other metal regions 136A, 136B, and 136C that are in electrical contact with tungsten plugs 134A, 134B, and 134C, respectively. 
     Other Ferroelectric Devices 
     FIGS. 85-89 illustrate a method of protecting any ferroelectric device resident on an integrated circuit from hydrogen damage, the method comprising the step of encapsulating the ferroelectric device with a hydrogen-barrier cap layer distinct from the ferroelectric device. 
     Referring now to FIG. 85, a semiconductor or other substrate 100 is shown. A ferroelectric device 140 is shown having first and second metal contacts 142 and 144. Although only two contacts are shown, any number can be used. Ferroelectric device 140 can be an integrated or bulk capacitor, transistor, sensor, or any other device containing a ferroelectric material that can be damaged in subsequent semiconductor processing steps. 
     In FIG. 86, ferroelectric device 140 including contacts 142 and 144 is covered with a cap layer 122. Cap layer 122 can be formed of a ferroelectric material including doped and undoped PZT, BST, and SBT, or other known ferroelectric materials. Cap layer 122 can also be a ferroelectric or non-ferroelectric ceramic material selected from a group consisting of doped and undoped nitrides, titanates, zirconates, niobates, tantalates, stanates, hafnates, and manganates. The thickness of layer 122 is determined by the dimensions of ferroelectric device 140 and other processing constraints. While nominal levels can be similar to those described in this disclosure, other thicker layers can be used if desired. 
     In FIG. 87, cap layer 122 is etched to completely encapsulate ferroelectric device 140 and to provide vias 146 and 148 to access metal contacts 142 and 144. 
     In FIG. 88, metal contacts 142 and 144 are metalized with aluminum or other known metalization materials to provide electrical contact to other portions of the integrated circuit. 
     In FIG. 89, an oxide layer or passivation layer 126 is formed and, if desired, planarized. 
     Having described and illustrated the principles of the invention in a preferred embodiment thereof, it is appreciated by those having skill in the art that the invention can be modified in arrangement and detail without departing from such principles. For example, the following aspects of the semiconductor processes described herein can be changed as required: the types of dielectric materials; the thicknesses of the various layers; the types of ferroelectric materials; the etching processes; the electrode materials; and the anneal temperatures, durations, and numbers. Also, the specific application of the ferroelectric capacitor of the present invention is not limited to ferroelectric memory cells, although it is ideally suited to that application. We therefore claim all modifications and variation coming within the spirit and scope of the following claims.