`Havemann
`
`lIllllllllllllllllllllllllll?ggmglllIllllllllllllllllllllllllllllllll
`
`2894A
`[11] Patent Number:
`[45] Date of Patent:
`
`5,482,894
`Jan. 9, 1996
`
`[54] METHOD OF FABRICATING A
`SELF-ALIGNED CONTACT USING
`ORGANIC DIELECTRIC MATERIALS
`
`FOREIGN PATENT DOCUMENTS
`
`0105923 5/1991 Japan.
`0127454 4/1992 Japan.
`
`[75] Inventor: Robert H. Havemann, Garland, Tex.
`
`OTHER PUBLICATIONS
`
`[73] Assignee: Texas Instruments Incorporated,
`Dallas, Tex.
`
`[21] Appl. No.: 294,290
`[22] Filed:
`Aug. 23, 1994
`
`[51] Int. C1.6 ................................................... .. H01L 21/44
`[52] US. Cl. ........................ .. 437/195; 437/228; 437/236;
`437/203; 156/644.1; 156/651.1
`[58] Field of Search ................................... .. 437/195, 231,
`437/52, 48, 60, 228, 235, 236, 203, 919,
`238; 156/644.1, 651.1
`
`[56]
`
`References Cited
`
`U.S. PATENT DOCUMENTS
`
`3/1986 Chiang .................................. .. 430/313
`4,576,900
`4,683,024 7/1987 Miller et a1. ..
`156/643
`
`4,980,316 12/1990 Huebner . . . . . . . .
`
`. . . .. 437/228
`
`5,037,777
`8/1991 Mele et al. . . . .
`5,069,747 12/1991 Cathey et a1.
`
`. . . .. 437/195
`156/643
`
`5,100,838
`
`3/1992 Dennison . . . . . .
`
`. . . .. 437/195
`
`5,198,298
`5,200,358
`
`3/1993 Haskell et a1. . . . .
`4/1993 Bollinger et al. .
`
`. . . .. 428/336
`437/180
`
`5,246,883
`
`9/1993 Lin et al. . . . . . . . . . .
`
`. . . .. 437/195
`
`5,279,989
`
`1/1994 Kim . . . . . . . . . . . . . .
`
`. . . .. 437/195
`
`5,371,047 12/1994 Greco et a1. . . . . . .
`. . . .. 437/238
`5,393,712
`2/1995 Rostoker et a1. ..................... .. 437/235
`
`Ser. No. 08/234,100, Apr. 27, 1994, Havemann.
`Ser. No. 08/234,099, Apr. 27, 1994, Havemann
`Primary Examiner—Tuan H. Nguyen
`Attorney, Agent, or Firm—Jarnes E. Harris; Richard L.
`Donaldson; Richard A. Stoltz
`[57]
`ABSTRACT
`
`A semiconductor device and process for making the same
`are disclosed which incorporate organic dielectric materials
`to form self-aligned contacts (SACTs) reliably, even in deep,
`narrow gaps. In one embodiment, conductors 26 with insu
`lating conductor caps 28 are formed over a silicon substrate
`20 with a thin gate oxide 22. A conformal dielectric layer 30,
`preferably of thermally-grown oxide, is deposited over this
`structure, which is then covered with an organic-containing
`layer 32 and an inorganic cap layer 34 (e.g., CVD TEOS).
`An etch window 38 is patterned in photoresist layer 36 and
`used as a mask to etch cap window 39 through layer 34,
`using layer 32 as an etch stop. A second etch removes
`organic-containing layer 32 in contact window 41 (and
`preferably strips photoresist), using conformal layer 30 as an
`etch stop. A short anisotropic etch may be used to clear
`conformal layer 30 from gap bottom 43, after which con
`ducting material 40 may be used to make electrical contact
`to the substrate.
`
`11 Claims, 5 Drawing Sheets
`
`Petitioner Hynix - HYNIX-1004
`
`1
`
`
`
`US. Patent
`
`Jan. 9, 1996
`
`Sheet 1 of 5
`
`5,482,894
`
`FIG. 1A
`
`/////////////7//
`
`18
`
`16
`
`A)
`
`22
`
`28
`‘h /
`26
`,24
`FIG. 1B \ 1
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`
`'38
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`26
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`
`.19
`
`FIG 7C
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`
`30
`
`22
`
`2
`
`
`
`US. Patent
`
`Jan. 9, 1996
`
`Sheet 2 of 5
`
`5,482,894
`
`FIG. 7D
`
`FIG. 1E
`
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`E
`
`3
`
`
`
`US. Patent
`
`Jan. 9, 1996
`
`Sheet 3 of 5
`
`5,482,894
`
`FIG.
`
`4 3
`
`2 3_
`
`G N
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`1
`.1 m
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`\\\\\
`
`8 2
`6_ 2
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`x
`A) 43
`
`3 4
`
`nay/1|
`3/4
`Mvv/mwm w
`
`K43
`
`4
`
`
`
`U.S. Patent
`
`Jan. 9, 1996
`
`Sheet 4 of s
`
`5,482,894
`
`F. F
`
`B 2
`
`m n
`
`%\./ m 9
`/ 6.
`2
`
`m/7
`
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`
`m H
`
`5
`
`
`
`US. Patent
`
`Jan. 9, 1996
`
`Sheet 5 of 5
`
`b------
`_ _ a _ _
`
`FIG. 3
`
`6
`
`
`
`5,482,894
`
`1
`METHOD OF FABRICATIN G A
`SELF-ALIGNED CONTACT USING
`ORGANIC DIELECTRIC MATERIALS
`
`CROSS-REFERENCE TO RELATED
`APPLICATIONS
`The following co-assigned US. patent applications are
`hereby incorporated herein by reference:
`
`TI Case
`
`Ser. No
`
`Filing Date
`
`Inventor
`
`Title
`
`TI-19070 08/234,100
`
`4/27/94
`
`Havemann
`
`TI-l907l 08/234,099
`
`4/27/94
`
`I-Iavemarm
`
`Self-Aligned
`Via Using Low
`Permittivity
`Dielectric
`Via Formation
`In Polymeric
`Materials
`
`10
`
`20
`
`FIELD OF THE INVENTION
`
`This invention relates to fabrication of semiconductor
`devices and more particularly to the formation of self
`aligned contacts on such devices.
`
`25
`
`BACKGROUND OF THE INVENTION
`
`Semiconductors are widely used in integrated circuits for
`electronic devices such as computers and televisions. These
`integrated circuits may contain millions of transistors fab
`ricated on a single crystal silicon chip to perform complex
`functions and store data. Integrated circuits are commonly
`constructed by sequentially forming transistor active
`regions, insulating ?lms, and patterned conducting ?lms in
`a predetermined arrangement on a semiconductor substrate.
`Active regions and conducting ?lms must be accurately
`aligned if the circuit is to function properly; therefore,
`self-aligning features (features whose placement is at least
`partially determined by the location of previously fabricated
`features) are highly desirable.
`To facilitate extremely dense circuit layouts, it is desirable
`at times to fabricate the lowest conductor level (which
`typically includes transistor gates) with conductors at mini
`mum spacing. Unfortunately, such spacing may make a
`self-aligned contact (SACT) necessary for, e.g., electrically
`connecting to source/drain active regions located in the
`narrow gaps between the conductors. One method for form
`ing a SACT directly between closely spaced features is
`described by Bollinger, et al., in US. Pat. No. 5,200,358,
`issued on Apr. 6, 1993. In this method, ?rst and second
`dielectric layers are deposited over gate level conducting
`features. A selective etch process is used to facilitate the
`opening of contact holes between the conducting features.
`The selective etch process is designed to remove material
`from the second dielectric layer faster than it removes
`material from the ?rst dielectric layer. Silicon nitride and
`silicon dioxide (of different varieties) are used for the
`dielectric layers; relative etch selectivity for the best of such
`dielectric combinations is on the order of 10:1.
`A method such as that described in the ’358 patent is
`generally useful when the aspect ratio (ratio of gap height to
`gap width) of the gap between the conducting features is
`low; as the aspect ratio increases (which it generally does
`when device geometries shrink), the ?rst dielectric layer
`must be made increasingly thick to insure that the insulation
`protecting the underlying conducting features will not be
`
`30
`
`35
`
`40
`
`45
`
`50
`
`55
`
`65
`
`2
`perforated during contact window etching. At some geom
`etry, this method becomes ineffective for reliably forming
`such self-aligned contacts; the limited selectivity between
`dielectric layers and limited etch anisotropy (ability to etch
`in one direction only, e.g. vertically) make such a process
`di?icult for high aspect ratio gaps.
`
`SUMMARY OF THE INVENTION
`
`The present invention relates to a method of producing
`and a structure for self-aligned contacts on semiconductor
`devices. This is apparently the ?rst self-aligned contact
`design capable of reliably forming contacts in narrow,
`high-aspect ratio gaps (e.g., less than 0.5 pm wide, 2:1 and
`greater aspect ratios). However, the invention may provide
`advantages for SACTs in general: a high quality conformal
`dielectric such as thermal oxide may be used as insulation
`between an SACT and adjacent conductors; this oxide may
`be made relatively thin for enhancing a capacitive storage
`node (e.g. DRAM applications); “notching” of such insula
`tion may be prevented; a dielectric with excellent gap-?ll,
`planarity, a relatively low dielectric constant, and etch
`selectivity to oxide greater than 100:1 is provided. These and
`other advantages will become apparent after reading this
`disclosure.
`Organic-containing materials have many perceived dis
`advantages which have, in general, precluded their use as
`semiconductor dielectrics. These disadvantages include:
`instability and out-gassing at modest (generally less than
`500° C.) temperatures; application by wet methods where
`vapor deposition is preferred; and an incapacity to withstand
`photoresist stripping operations. However, it has now been
`found that certain organic-containing materials are substan
`tially unaffected by etching which is wholly effective on
`materials such as oxides and nitrides; conversely, the present
`invention includes etch procedures which may selectively
`remove such organic-containing materials without substan
`tially affecting exposed inorganic dielectrics (e.g., oxide or
`nitride).
`Consequently, the present invention includes a method of
`forming a self-aligned contact on a semiconductor device. In
`this method, two conductors of a predetermined height are
`provided on a substrate, preferably with each containing an
`insulating conductor cap at least in the vicinity where the
`SACT is to be formed. These conductors are preferably
`separated by a predetermined spacing. Over these conduc
`tors and the surrounding substrate, a conformal dielectric
`layer may be formed, thereby creating an insulated gap of
`predetermined width between the conductors. An organic
`containing dielectric layer may then be deposited over the
`conductors, preferably to a depth su?icient to completely
`cover the conductors and ?ll the insulated gap. An inorganic
`cap layer may then be deposited over the organic-containing
`dielectric layer. A cap window may be etched through the
`cap layer, substantially vertically aligned with the insulated
`gap, preferably using the organic-containing dielectric layer
`as an etch stop. A contact window may subsequently be
`etched through the organic-containing dielectric layer, using
`the cap window as a mask, and using an etchant which does
`not substantially affect the conformal dielectric layer mate
`rial.
`Preferably, a short anisotropic etch of the conformal layer
`follows these steps if contact is to be made to the substrate
`in the gap (which may then be followed by a deposition of
`conducting material in the gap to form an electrical contact
`to the substrate). The insulating conductor cap may prefer
`ably be comprised principally of silicon dioxide, silicon
`
`7
`
`
`
`5,482,894
`
`3
`nitride, or silicon oxynitride. The conformal dielectric layer
`may likewise be comprised of one or more layers of silicon
`dioxide, silicon nitride, or silicon oxynitride (and most
`preferably of thermally-grown oxide). As an aid to process
`ing, it is preferable that the organic-containing dielectric
`layer etching step also strip any photoresist which may exist
`at that point above the cap layer.
`The present invention also provides a structure for a
`self-aligned contact comprising two conductors formed on a
`substrate, substantially parallel over a predetermined length,
`and separated by a predetermined spacing. These conductors
`preferably include an insulative conductor cap, at least in the
`vicinity of the self-aligned contact. The structure further
`comprises a conformal dielectric layer adhering at least to
`the facing sides of the two conductors, thereby creating an
`insulated gap of predetermined Width between the conduc
`tors (the conformal layer may be found on other portions of
`the conductors or substrate, since this may simplify process
`ing). The structure may further comprise a conducting
`material disposed in the insulated gap, at least along one
`section of the predetermined length. The structure further
`comprises an organic-containing dielectric layer disposed in
`portions of the insulated gap other than the section ?lled
`with conducting material. An inorganic cap layer may be
`deposited overlying the organic-containing dielectric layer.
`The conducting material may contact the substrate in the
`gap between the conductors. The two conductors may con
`tain multiple conducting sublayers (preferably a polysilicon
`underlayer and a polycide overlayer). The organic-contain
`ing layer preferably contains 10% to 100% by weight
`organic material, preferably with the remainder comprised
`substantially of silicon dioxide.
`
`BRIEF DESCRIPTION OF THE DRAWINGS
`
`This invention, including various features and advantages
`thereof, can be best understood by reference to the following
`drawings, wherein:
`FIGS. 1A-1I show cross-sectioned elevations of one
`embodiment of a self-aligned contact made according to a
`method of the invention;
`FIGS. 2A-2D show a cross-sectioned elevation of a
`second embodiment wherein a conformal layer is con
`structed in multiple steps;
`FIG. 3 shows a cross-sectioned elevation of an embodi
`ment wherein no contact is made to the substrate; and
`FIG. 4 shows a top view of a typical embodiment (which
`may be applicable to any of the above embodiments) to
`illustrate lateral positioning of a contact.
`
`DETAILED DESCRIPTION OF THE
`PREFERRED EMBODIMENTS
`
`One method of forming a SACT by the present invention
`is illustrated in FIG. 1. In FIG. 1A, a thin gate oxide 22 (e.g.
`of thermally-grown silicon dioxide) is shown over a sub
`strate 20. A conducting layer 16, which may be polysilicon
`with a refractory metal silicide overlayer (not shown), is
`deposited over the gate oxide, followed by insulating layer
`18, which may, for example, be additional thermally-grown
`oxide.
`FIG. 1B shows the structure after patterning and etching
`by known methods to form two conductors 26, including
`insulating conductor caps 28, separated by a gap 24 with a
`relatively high aspect ratio (1.4:1 aspect ratio shown). FIG.
`1C shows a conformal dielectric layer 30 (e. g. of thermally
`grown oxide) over gate oxide 22, conductors 26 and con
`
`10
`
`25
`
`30
`
`35
`
`45
`
`50
`
`55
`
`60
`
`65
`
`4
`ductor caps 28. Layer 30 adheres to the facing walls of
`conductors 26, forming insulated gap 29. With a dielectric
`layer 30 deposition thickness only 15% the width of gap 24
`(FIG. 1B), the aspect ratio of insulated gap 29 is shown to
`be 2:1, illustrating the desirability of a method which
`requires only a thin dielectric layer 30.
`FIG. 1D shows several additional layers, the ?rst of which
`is an organic~containing dielectric layer 32, preferably
`deposited to ?ll insulated gap 29 as well as cover conductors
`26 (including conformal layer 30). Layer 32 may be con
`stituted, for example, of a spin-on glass (SOG) such as the
`Allied Signal 515 series low-k (dielectric constant of about
`2) SOG, which contains 30%—40% organic polymer by
`weight. After application and drying of organic-containing
`layer 32, the entire intermediate structure is preferably
`annealed, e.g. at 425° C. for 60 minutes in a nitrogen
`atmosphere. An inorganic cap layer 34 may then be depos
`ited over layer 32 by one of several known methods,
`including plasma-enhanced chemical vapor deposition
`(CVD) of silicon dioxide from tetraethoxysilane (TEOS).
`The cap layer should, in general, be designed such that it will
`not be totally removed by later etch steps. A layer of
`photoresist 36 may subsequently be applied over cap layer
`34 in preparation for patterning.
`FIG. 1E illustrates an etch window 38 formed in photo
`resist 36. This etch window is preferably wider than, and
`substantially vertically aligned with, insulated gap 29. FIG.
`1F shows that etch window 38 supplies a pattern for etching
`cap layer 34 to create cap window 39. Preferably, organic
`containing layer 32 acts as an etch stop to this process. It has
`been found, for example, that ?uorocarbon etchants (e.g.,
`CZFG) in a high density plasma (HDP) reactor, such as the
`commercially available Applied Materials Omega-Centura
`5300, etch TEOS oxide, e.g. layer 34, and yet do not
`substantially etch materials similar to organic-containing
`example Allied Signal 515 Series (e.g. layer 32).
`Cap window 39 supplies a pattern for etching a contact
`window through organic-containing layer 32 by a suitable
`anisotropic (substantially in one direction, usually vertical)
`etch. As shown in FIG. 16, a contact window 41 is prefer
`ably etched through organic-containing layer 32, preferably
`clearing the portion of layer 32 directly underlying cap
`window 39 and stopping on layer 30. This etch may, for
`example, be accomplished using an 02 plasma etch in the
`aforementioned HDP reactor. Advantageously, this etch may
`also be used to simultaneously strip photoresist 36 from the
`device. Note that after removal of the photoresist, cap layer
`34 acts as a hard mask, preventing the 02 plasma etch from
`affecting the organic-containing layer in regions other than
`contact window 38.
`As shown in FIG. 1H, a short anisotropic etch may be
`used to remove conformal layer 30 and gate oxide 22 from
`gap bottom 43. Such an etch may thin cap layer 34, as
`shown, particularly if similar materials are used for both
`layers 30 and 34. This etch also generally attacks layer 30
`where it covers the top comers of conductors 26, since these
`corners are exposed by an oversized and/or misaligned
`contact window, as shown. This situation may necessitate
`insulating conductor caps 28 simply to provide etch margin
`above conductors 26; otherwise, conductors 26 might be
`exposed by the etch of conformal layer 30, resulting in the
`formation of a short in the ?nal structure. Finally, as illus
`trated in FIG. 11, contact plug 40, formed of a conducting
`material (e.g. a composite comprised of a refractory metal
`underlayer with a tungsten overlayer) may be deposited in
`cap window 39 and contact window 41 (which includes the
`portion of insulated gap 29 underlying window 39) to form
`
`8
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`5,482,894
`
`6
`The following table provides an overview of some
`embodiments cross-referenced to the drawings.
`
`Drawing Preferred or
`Element Speci?c Examples
`
`Generic Term
`
`Other Alternate
`Examples
`
`5
`a contact to the substrate at gap bottom 43.
`A second SACT embodiment is illustrated in FIGS.
`2A-2D. The intermediate structure as shown in FIG. 2A
`may, for example, be constructed in a manner similar to FIG.
`1C. However, this intermediate structure is then anistropi
`cally etched by known methods to remove conformal dielec
`tric 30 (and possibly gate oxide 22) from horizontal exposed
`surfaces. This step may thin conductor caps 28 (as shown).
`Conformal dielectric 30 deposited on the sidewalls of con
`ductors 26 may also be thinned at this point (e.g., if layer 30
`is used in a known manner to align ion implantation to
`substrate 20, layer 30 may require thinning after implanta
`tion to reduce the aspect ratio of insulated gap 29)._
`Additional material may subsequently be deposited as a
`conformal dielectric overlayer 42, e.g., using thermal oxide
`or silicon nitride (see FIG. 2C). This layer provides a
`minimal protection for substrate 20 during the 02 plasma
`etch to remove organic-containing material from insulated
`gap 29. FIG. 2D shows this embodiment after additional
`deposition and patterning similar to that of the ?rst embodi
`ment. However, notching of conductor caps 28 prevalent in
`the prior art is virtually eliminated, because only the
`extremely thin overlayer 42 must be removed to open the
`contact window to substrate 20. If conformal layer 30 and
`overlayer 42 diifer in materials (e.g. thermal oxide and
`nitride), relative selectivity between the two materials may
`also be exploited to design a structure wherein conductor
`caps 28 are extremely thin.
`Conductor caps 28 may be totally eliminated from an
`embodiment, for example, if connection to the substrate is
`not required (e. g. some capacitor applications). In FIG. 3, an
`embodiment is shown with a large cap window 39, no
`insulating caps over conductors 26, and a thin conformal
`layer 30 (which may be as thin as can be produced with
`reliable coverage of the underlying structure). The
`extremely high selectivity of the aforementioned 02 plasma
`etch allows for complete removal of organic-containing
`layer 32 in contact window 41 (including the underlying
`portion of insulated gap 29), without disturbing layer 30.
`Contact plug 40 is then deposited in window 41. By decreas
`ing the insulation thickness between 40 and 26 (particularly
`directly above conductors 26, where prior art thickness must
`be large to compensate for notching), this embodiment may
`advantageously provide a large capacitance between contact
`40 and conductors 26.
`FIG. 4 shows a top view of an embodiment of the
`invention to illustrate another possible advantage of the
`present invention. Although contact plug 40 preferably
`occupies a lateral portion of gap 29 between conductors 26
`(which include, e.g., layer 30, not shown), these conductors
`may typically extend well past the contact plug in a longi
`tudinal direction. In such an instance, the low dielectric
`constant properties of many organic-containing dielectrics
`(as compared to oxide or nitride) may advantageously lower
`crosstalk, switching delays, and power consumption due to
`undesired capacitance between neighboring conductors 26,
`in areas other than the location of the contact. These con
`siderations become particularly important for high-aspect,
`closely spaced conductors, an application to which the
`present invention is ideally suited.
`
`15
`
`25
`
`30
`
`35
`
`40
`
`45
`
`50
`
`55
`
`60
`
`65
`
`Substrate
`
`Gate oxide
`
`Silicon nitride
`
`20
`
`22
`
`26
`
`28
`
`30
`
`32
`
`34
`
`36
`4O
`
`Single-crystal
`silicon
`Thermally-grown
`oxide (Si02)
`Polysilicon w/
`refractory metal
`silicide
`overlayer
`Thermally-grown
`oxide
`
`Conductors
`
`Insulating
`conductor cap
`
`Thermally-grown
`oxide
`
`Confonnal
`dielectric layer
`
`Allied Signal 515
`Series SOG
`
`CVD silicon
`dioxide
`
`Organic-
`containing
`dielectric layer
`Inorganic cap
`layer
`
`Photoresist
`Contact plug
`
`Tungsten w/
`refractory metal
`underlayer
`
`Aluminum,
`copper, tungsten,
`platinum, titanium
`
`CVD oxide,
`silicon nitride,
`doped oxides,
`silicon oxynitride
`CVD oxide,
`silicon nitride,
`silicon oxynitride
`Amorphous
`Te?on, parylene,
`polyimide
`Inorganic SOG,
`silicon nitride,
`doped oxides,
`silicon oxynitride
`
`Aluminum,
`polysilicon,
`copper, titanium,
`tantalum, titanium
`nitride, refractory
`metal silicides
`Thermal oxide,
`CVD oxide
`
`42
`
`Silicon nitride
`
`Conformal
`dielectric
`overlayer
`
`The invention is not to be construed as limited to the
`particular examples described herein, as these are to be
`regarded as illustrative, rather than restrictive. The invention
`is intended to cover all processes which do not depart from
`the spirit and scope of the invention. For example, dopants
`may be introduced to the substrate at various points during
`the practice of the invention. A gate oxide is not critical to
`the invention, as the invention may be practiced, e. g., using
`conductors constructed over ?eld oxide. Either the organic
`containing or cap layer may be planarized, e.g. by chemical
`mechanical polishing or blanket etchback techniques, during
`the practice of the invention.
`What is claimed is:
`1. A method of fabricating a self-aligned contact on a
`semiconductor device comprising:
`(a) providing two separated conductors on a substrate;
`(b) forming a conformal dielectric layer over said con
`ductors and said substrate, thereby creating an insulated
`gap having a ?rst width between said conductors;
`(c) depositing an organic-containing dielectric layer over
`said conductors and said substrate to a depth su?icient
`to completely cover said conductors and ?ll said insu
`lated gap;
`((1) depositing an inorganic cap layer over said organic
`containing dielectric layer;
`(e) etching a cap window through said cap layer, said cap
`window substantially vertically aligned with said gap
`and having a second width greater than said ?rst width;
`and
`(f) etching a contact window through said organic-con
`taining dielectric layer, using said cap window as a
`mask for said contact window, and using an etchant
`
`9
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`5,482,894
`
`7
`which does not substantially affect said conformal
`dielectric layer, whereby a lower portion of said contact
`window is laterally con?ned to said insulated gap, and
`whereby said conformal dielectric layer is left substan
`tially intact by said etching steps.
`2. The method of claim 1, wherein said conductors each
`contain an insulating conductor cap.
`3. The method of claim 2, further comprising: anisotro
`pically etching exposed portions of said conformal dielectric
`layer in said contact window to expose said substrate in at
`least a portion of said insulated gap; and depositing a
`conducting material in said contact window to provide
`electrical contact to said substrate.
`4. The method of claim 1, wherein said forming a con
`formal dielectric layer step comprises:
`(a) depositing dielectric material conformally over said
`conductors and said substrate;
`(b) anisotropically etching said dielectric material such
`that said dielectric material is substantially removed
`from horizontal surfaces of said conductors and said
`substrate; and
`(c) depositing a conformal dielectric overlayer over said
`conductors and said substrate.
`5. The method of claim 1, wherein said conformal dielec
`tric layer is comprised of materials selected from the group
`consisting of thermally-grown oxide, CVD silicon dioxide,
`doped oxide, silicon nitride, silicon oxynitride, and combi
`nations thereof.
`6. The method of claim 1, wherein a patterned photoresist
`layer overlying said cap layer is used to facilitate said
`etching a cap window through said cap layer step, and
`wherein said etching a contact window through said organic
`containing dielectric layer step simultaneously removes said
`photoresist layer.
`7. The method of claim 1, wherein said organic-contain
`ing dielectric layer acts as an etch stop for said etching a
`contact window through said cap layer step.
`8. The method of claim 1, wherein said organic-contain
`ing dielectric contains between 10 and 100 percent by
`weight organic material.
`9. The method of claim 8, wherein said organic-contain
`ing dielectric consists essentially of said organic material
`and silicon dioxide.
`10. A method of fabricating a self-aligned contact on a
`semiconductor device comprising:
`
`10
`
`25
`
`35
`
`8
`(a) providing two separated conductors formed on a
`substrate, said conductors having insulating conductor
`caps;
`(b) forming a conformal dielectric layer over said con
`ductors and said substrate, thereby creating an insulated
`gap between said conductors;
`(c) depositing an organic-containing dielectric layer over
`said conductors and said substrate to a depth su?icient
`to completely cover said conductors and ?ll said insu
`lated gap;
`(d) depositing an inorganic cap layer over said organic
`containing dielectric layer;
`(e) depositing a photoresist layer over said cap layer and
`patterning an etch window through said photoresist
`layer, said etch window being substantially vertically
`aligned with and being wider than said insulated gap;
`(f) etching a cap window through said cap layer, using
`said etch window as a mask for said cap window, and
`using said organic-containing dielectric layer as an etch
`stop;
`(g) etching a contact window through said organic-con
`taining dielectric layer, using said cap window as a
`mask for said contact window, and using an etchant
`which does not substantially affect said conformal
`dielectric layer, said etching a contact window step also
`removing said photoresist layer;
`(h) anisotropically etching exposed portions of said con
`formal dielectric layer in said contact window to
`expose said substrate in at least a portion of said
`insulated gap; and
`(i) depositing a conducting material in said contact win
`dow to provide electrical contact to said substrate,
`whereby an electrical contact to said substrate is later
`ally positioned by said insulated gap, and whereby
`capacitive coupling between said conductors is
`decreased, as compared to a solid silicon dioxide
`dielectric.
`11. The method of claim 10, further comprising, before
`said depositing an inorganic cap layer step, thinning said
`organic-containing layer with a blanket etchback.
`
`10