`US00554l434A
`
`United States Patent
`
`[19]
`
`[11] Patent Number:
`
`5,541,434
`
`Nicholls et al.
`
`[45] Date of Patent:
`
`Jul. 30, 1996
`
`6/1988 European Pat. Off. .
`0272050
`6/1988 European Pat. Oif. .
`027205lA2
`8/1990 European Pat. O11”.
`.
`0308964A2
`3/1988
`Japan ................................... .. 257/640
`63-62380
`ll/1988 Japan .
`63—278256
`257/900
`1/1990
`Japan .
`2-28939
`257/383
`6/1990
`Japan .
`2-156542
`
`3-278576 12/1991
`Japan ................................... .. 257/640
`
`Primary Examiner—Sara W. Crane
`Assistant Examt'rter—Courtney A. Bowers
`Attorney, Agent, or Firm——Felsman, Bradley, Gunter &
`Dillon, LLP
`
`[57]
`
`ABSTRACT
`
`A semiconductor device comprising a silicon substrate, an
`oxide layer on the silicon substrate, a doped polysilicon
`region disposed on the oxide layer, a dielectric layer which
`has been deposited over the doped polysilicon region and the
`silicon substrate, a contact hole which is formed in the
`dielectric layer and extends over respective laterally adja-
`cent portions of the doped polysilicon region and the silicon
`substrate and a Contact which has been selectively deposited
`in the contact hole which electrically connects the said
`portions together. The invention also provides a method of
`fabricating a semiconductor device incorporating a refrac-
`tory metal contact, the method comprising the steps of: a)
`providing a semiconductor substrate having an oxide layer
`thereon and a doped polysilicon region disposed on the
`oxide layer; (b) depositing a dielectric layer over the doped
`polysilicon region and over the silicon substrate; (c) forming
`a contact hole in the dielectric layer which exposes a portion
`of the doped polysilicon region and a laterally adjacent
`portion of the silicon substrate; and (d) selectively deposit-
`ing a contact into the contact hole thereby electrically to
`connect together the doped polysilicon region and the silicon
`substrate.
`
`10 Claims, 7 Drawing Sheets
`
`[54] SEMICONDUCTOR DEVICE
`INCORPORATING A CONTACT FOR
`ELECTRICALLY CONNECTING ADJACENT
`PORTIONS WITHIN THE SEMICONDUCTOR
`DEVICE
`
`[75]
`
`Inventors: Howard C. Nicholls, Wales; Michael
`J. Norrington, Essex, both of United
`Kingdom
`
`[73] Assignee:
`
`Inmos Limited, United Kingdom
`
`[21] Appl. No.2 119,519
`
`[22] Filed:
`
`Sep. 10, 1993
`
`[30]
`
`Foreign Application Priority Data
`
`Sep. 11, 1992
`
`[GB]
`
`United Kingdom ................... 9219268
`
`Int. Cl.6 ..................................................... H01L 29f76
`[51]
`[52] U.S. Cl.
`........................... 257/383; 257/641; 257/900
`[58] Field of Search ................................... .. 257/382, 383,
`257/900, 393, 640, 641, 649, 903, 344,
`408
`
`[56]
`
`References Cited
`U.S. PATENT DOCUMENTS
`
`8/1977 Hall.
`4,042,953
`8/1989 Josquin ................................... 257/383
`4,359,630
`3/1990 Sander et al. .
`4,912,540
`3/1992 Murayama .............................. .. 357/71
`5,099,308
`9/1992 Miura et al.
`..
`.. 257/330
`5,148,247
`5/1993 Adan ...... ..
`257/393
`5,210,429
`8/1993 Liao .............
`257/344
`5,234,850
`9/1993 Nishigoori
`.............................. 257/383
`5,245,210
`FOREIGN PATENT DOCUMENTS
`
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`
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`12/1933 European Fat. 011.
`0094559Al
`0127020/X2 12/1984 European Pat. Off. .
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`U.S. Patent
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`Jul. 30, 1996
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`U.S. Patent
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`Jul. 30, 1996
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`U.S. Patent
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`Jul. 30, 1996
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`1
`SEMICONDUCTOR DEVICE
`INCORPORATING A CONTACT FOR
`ELECTRICALLY CONNECTING ADJACENT
`PORTIONS WITHIN THE SEMICONDUCTOR
`DEVICE
`
`BACKGROUND TO THE INVENTION
`
`The present invention relates to a semiconductor device
`incorporating a contact and to a method of fabricating such
`a semiconductor device.
`
`is
`In CMOS semiconductor devices and processes it
`known to employ electrical contacts between polysilicon,
`such as a polysilicon signal line, which signal line may
`integrally connect with a polysilicon gate layer, and diffu-
`sion silicon, such as a doped region of the silicon substrate
`of the device, which doped region is an active area of the
`device. Such polysilicon/dilfusion silicon contacts have in
`the past been produced by forming two contact holes in the
`dielectric layer which overlies the polysilicon and the dif-
`fusion silicon, one Contact hole extending down to the upper
`surface of the polysilicon and another contact hole spaced
`from the first contact hole extending down to the diffusion
`silicon. A metal wire is then located in the two contact holes
`and extends therebetween over the region of the dielectric
`layer which is located between the two contact holes. The
`known arrangement has layout disadvantages because each
`contact is subject to spacing constraints which are imposed
`by the requirement electrically to isolate any two contacts.
`It is also known to employ a local interconnect layer, for
`example of titanium nitride or titanium silicide, as a strap
`which connects the polysilicon to the diffusion silicon with
`the strap extending over the upper surface of the polysilicon
`and of the diffusion silicon. The local interconnect layer is
`formed after the patterning of the polysilicon but before the
`deposition of the dielectric layer whereby the strap is
`covered by the dielectric layer. This arrangement suffers
`from the disadvantage that the manufacturing process is
`relatively complex since additional deposition and etch steps
`for the local interconnect layer are required.
`In addition, it is also known to employ local removal of
`gate oxide between polysilicon and active silicon to produce
`a direct electrically conducting contact which is a buried
`contact. However, this method is limited to connecting N+
`polysilicon to N+ active silicon because, if opposite types
`are attempted to be connected, subsequent heat treatment
`steps at greater than 800° C. can cause parasitic diodes to be
`formed in the diffusion silicon.
`
`It is well known to employ an aluminium metal contact
`which is deposited by sputtering in a contact hole in a
`dielectric layer and extends down either to the polysilicon
`i.e. to a signal line or to the diffusion silicon substrate i.e. to
`an active area. It has been proposed to provide a contact
`between the polysilicon and the diifusion silicon by forming
`a contact of aluminium metal in the form of a strap which
`extends over both the polysilicon and the diffusion silicon.
`However, such aluminium contacts suffer from the disad-
`vantage that the lateral dimensions of the contact hole and
`the contact are relatively large in order to enable the alu-
`minium reliably to form the contact with elfective electrical
`connections.
`
`SUMMARY OF THE INVENTION
`
`The present invention provides a semiconductor device
`comprising a silicon substrate, an oxide layer on the silicon
`substrate, a doped polysilicon region disposed on the oxide
`
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`layer, a dielectric layer which has been deposited over the
`doped polysilicon region and the silicon substrate, a contact
`hole which is formed in the dielectric layer and extends over
`respective laterally adjacent portions of the doped polysili-
`con region and the silicon substrate and a contact which has
`been selectively deposited in the contact hole which elec-
`trically connects the said portions together.
`The present invention also provides a method of fabri-
`cating a semiconductor device incorporating a refractory
`metal contact,
`the method comprising the steps of:
`(a)
`providing a semiconductor substrate having an oxide layer
`thereon and a doped polysilicon region disposed on the
`oxide layer; (b) depositing a dielectric layer over the doped
`polysilicon region and over the silicon substrate; (c) forming
`a contact hole in the dielectric layer which exposes a portion
`of the doped polysilicon region and a laterally adjacent
`portion of the silicon substrate; and (d) selectively deposit-
`ing a contact into the contact hole thereby electrically to
`connect together the doped polysilicon region and the silicon
`substrate.
`
`BRIEF DESCRIPTION OF THE DRAWINGS
`
`invention will now be
`Embodiments of the present
`described by way of example only with reference to the
`accompanying drawings, in which:
`FIGS. 1a to 1e are schematic sections through a silicon
`wafer structure showing sequentially a series of process
`steps for manufacturing a semiconductor device in accor-
`dance with a first embodiment of the present invention;
`FIGS. 2a to 2f are schematic sections through a silicon
`wafer structure showing sequentially a series of process
`steps for manufacturing a semiconductor device in accor-
`dance with a second embodiment of the present invention;
`FIGS. 3a to 3d are schematic sections through a silicon
`wafer structure showing sequentially a series of process
`steps for manufacturing a semiconductor device in accor-
`dance with a third embodiment of the present invention; and
`FIGS. 4a to 4d are schematic sections through a silicon
`wafer structure showing sequentially a series of process
`steps for manufacturing a semiconductor device in accor-
`dance with a fourth embodiment of the present invention.
`
`DETAILED DESCRIPTION OF THE
`PREFERRED EMBODIMENTS
`
`Referring to FIGS. 1a to 1e there is shown a process flow
`for the manufacture of a semiconductor device in accor-
`
`dance with the first embodiment of the present invention. A
`substrate 2 of difi°usion silicon is provided with a gate oxide
`layer 4 which has been grown thereover so as preferably to
`have a thickness of from 50 to 500 Angstroms, more
`preferably approximately 200 Angstroms. A region 6 of
`doped polysilicon, the dopant being either of N+ or P+
`polarity depending on the semiconductor device being
`fonned, is subsequently grown and then patterned on the
`gate oxide layer 4. The region 6 of doped polysilicon acts,
`in the resultant semiconductor device, as a signal line and is
`integrally connected with a transistor gate layer of polysili-
`con which is located on the gate oxide layer over source and
`drain regions of the transistor. The polysilicon region 6
`preferably has a thickness of from 1000 to 6000 Angstorns,
`more preferably around 3000 Angstroms. The initial struc-
`ture is shown in FIG. la. As shown in FIG. lb, a dopant is
`then implanted into the silicon substrate so as to form active
`silicon implant regions 8,10 of the required polarity on
`opposed sides of the polysilicon region 6. The regions 8,10
`
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`5,541,434
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`3
`may be the same or opposite polarity as that of the doped
`polysilicon region 6. The polysilicon region 6 masks from
`dopant implantation that region 12 of the silicon substrate 2
`which is located thereunder. A dielectric layer 14, preferably
`of reflowable oxide, is then deposited over the polysilicon
`region 6 and the gate oxide 4 extending over the implant
`regions 8,10 and then the dielectric layer 14 is densified in
`a known manner. Preferably, the dielectric layer 14 has a
`deposited thickness of from 4000 to 12000 Angstroms, more
`preferably 7500 Angstroms (the thickness changing after
`subsequent reflow of the dielectric layer). The resultant
`structure is shown in FIG. 1c. Referring now to FIG. 1d a
`contact hole 16 is then etched in known manner in the oxide
`dielectric layer 14 and the gate oxide layer 4, with the
`contact hole being positioned so as to extend over both a
`portion of the polysilicon region 6 and a portion of the
`implanted region 10 of the silicon substrate 2, which por-
`tions are laterally adj acent.. Preferably, the contact hole etch
`is a dry etch which occurs in a fluorine- and carbon-
`containing plasma at pressures up to 4 Torr, and typically in
`the range of from 0.05 to 3 Torr. In this embodiment and in
`each of the other embodiments, the etching of the contact
`hole is controlled whereby there is a single etch step and
`polysilicon is not etched. However, a multiple etch step
`process may alternatively be employed. Thus the etching
`occurs down to the polysilicon gate and down to the silicon
`substrate without removal of silicon by the etch. The silicon
`structure is then subject
`to la reflow step at which the
`structure is heated, for example by a rapid thermal anneal, so
`as to reflow the dielectric layer 14 and form smoothed edges
`18 of the contact hole 16 thereby to facilitate subsequent
`deposition of a refractory metal therein. As is shown in FIG.
`le, a refractory metal, e.g.
`tungsten is then selectively
`deposited into the contact hole 16 so as to form a tungsten
`butting .contact 20 therein which electrically connects the
`polysilicon region 6 to the implanted region 10 of the silicon
`substrate 2. The upper surface of the tungsten butting contact
`20 may be covered by a dummy metal pad (not shown), for
`example of aluminium, the dummy metal pad being formed
`simultaneously when conventional interconnect layers are
`formed over the dielectric layer. Alternatively, the contact 20
`may be connected to the metal layer providing a metal to
`polysilicon to silicon substrate contact.
`A second embodiment of the present invention is illus-
`trated in FIGS. 2a to 2f, the second embodiment being a
`modification of the first embodiment. In the second embodi-
`ment, the initial structure is the same as that of the first
`embodiment in which a gate oxide layer 24 is grown over a
`silicon substrate 22 and then a doped polysilicon region 26
`is grown and patterned over the gate oxide layer 24. As is
`shown in FIG. 2b, a silicon nitride layer 28 preferably from
`200 to 1000 Angstroms thick, more preferably approxi-
`mately 400 Angstroms thick, is deposited over the polysili-
`con region 26 and the exposed parts of the gate oxide layer
`24. An implanting step is then carried out in which lightly
`doped implant regions 29,30 are formed in the silicon
`substrate 22 on opposed sides of the polysilicon region 26.
`The lightly doped regions 29,30 are laterally spaced from the
`polysilicon region 26 by a distance equal to the thickness of
`the silicon nitride layer 28 which acts to reduce tunneling or
`hot electron effects. The resultant structure is shown in FIG.
`
`21;. Referring now to FIG. 2c, a dielectric layer, for example
`an oxide layer, is then formed over the silicon nitride layer
`28 and then the dielectric layer is anisotropically etched
`back to form side wall spacers 31,32 of dielectric on
`opposed sides of the polysilicon region 26. The side wall
`spacers 31,32 preferably have a width at their lower extremi-
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`ties of around 2000 Angstroms. After the side wall spacers
`31,32 have been formed, a dopant is implanted into the
`silicon substrate 22 and into a respective lightly doped
`region 29,30 to form implanted regions 34,36 on opposed
`sides of the polysilicon region 26. Each implanted region
`34,36 has the same polarity as that of the respective adjacent
`lightly doped region 29,30 and is superimposed over that
`part of the respective lightly doped region 29,30 which is not
`masked by the respective sidewall spacer 31,32. Thus, the
`implanted regions 34,36 each have an edge which is defined
`by the edge of the respective side wall spacer 31,32, the side
`wall spacers 31,32 having acted to mask the lightly doped
`silicon regions 29,30 thereunder from dopant implantation.
`A dielectric layer 42 is then deposited over the structure
`of FIG. 2c to form the structure shown in FIG. 2d and then
`the dielectric layer 42 is densified in a known manner.
`Subsequently, as shown in FIG. 2e a contact hole 44 is
`etched in the dielectric layer 42 and the dielectric layer 42
`is reflowed as in the first embodiment to form reflowed
`edges 46 of the contact hole 44. The contact hole 44 is
`etched e.g. (in the manner described above with reference to
`the first embodiment) through the dielectric layer 42 and
`through the silicon nitride layer 28 which extends over the
`polysilicon region 26 and also through the gate oxide layer
`24 which is disposed over the implanted region 36 and the
`lightly doped region 30. The side wall spacer 32 may be
`removed during the formation of the contact hole 44. In the
`case where the oxide side wall spacer is only partially
`removed, the etch process acts to condition the surface of the
`oxide side wall spacer through surface polymer deposition
`and/or surface damage such that subsequent tungsten depo-
`sition occurs in a continuous film from the polysilicon, side
`wall spacer and active silicon surfaces. The resultant struc-
`ture is shown in FIG. 2e from which it will be seen that
`laterally adjacent portions of the polysilicon region 26 and
`of the implanted regions of the silicon substrate are exposed
`by the contact hole 44. The contact hole 44 is then filled with
`a selectively deposited tungsten contact 50 which covers the
`exposed part of the polysilicon region 26 and the implanted
`region 36 and the lightly doped region 29. As in the first
`embodiment, the top of the tungsten butted contact may be
`covered with a dummy metal layer 52 which is illustrated in
`FIG. 2f or connected to the metal layer.
`In an alternative arrangement instead of the lightly doped
`regions being formed before the implanted regions,
`the
`implanted regions 34,36 may be formed after the anistropic
`etching step to form the sidewall spacers whereby the
`sidewall spacers mask the regions to be lightly doped. The
`photoresist employed during the implanting step is left in
`place and then a wet etch is carried out to remove the sidwall
`spacers 31,32. A lightly doped implant is then performed in
`order to form the lightly doped regions 29,30.
`In the second embodiment, the silicon nitride layer 28 is
`employed laterally to space the lightly doped regions 29,30
`relative to the polysilicon region 26 and also to act as an etch
`stop during the anistropic etch to form the spacers. Further-
`more, the remaining silicon nitride layer 28 can act as a
`sealing layer adjacent the tungsten butting contact so as to
`inhibit the formation of tungsten silicide along the gate
`oxide/silicon interface in the manner disclosed in our EP-A-
`0391562 entitled “Semiconductor devices incorporating a
`tungsten contact and fabrication thereof’.
`A third embodiment of the present invention is illustrated
`in FIGS. 3a to 3d. This embodiment is a modification of the
`
`second embodiment. In the third embodiment, the sequence
`of process steps up to the formation of side wall spacers and
`the formation of the lightly doped regions and the implanted
`
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`5,541,434
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`5
`regions adjacent the spacers is the same as that of the second
`embodiment. FIG. 3a shows the structure in which a gate
`oxide layer 54 is disposed on a silicon substrate 52 and a
`polysilicon region 56 is disposed on the gate oxide layer 54.
`A silicon nitride layer 58 extends over the polysilicon layer
`56 and the gate oxide layer 54 and side wall spacers 60,62
`have been formed on opposed sides of the polysilicon region
`56. Implanted regions 64,66 and lightly doped regions 68,70
`are located in the silicon substrate 52 on respective opposed
`sides of the polysilicon region 56. Referring to FIG. 3b a
`second silicon nitride layer 72 is deposited over the poly-
`silicon layer 56, the side wall spacers 60,62 and the silicon
`nitride layer 58, and then a dielectric layer 74 is deposited
`over the silicon nitride layer 72 and subsequently densified.
`As is shown in FIG. 3c, a contact hole 76 is etched through
`the dielectric layer 74, the silicon nitride layers 72,58, the
`side wall spacer 62 and the gate oxide layer 54 so as to
`expose a portion of the polysilicon region 56 and, laterally
`adjacent thereto, the implanted region 66 and the lightly
`doped region 70. The etching may be performed in the
`manner described above with reference to the first embodi-
`ment. The dielectric material 74 is then reflowed to form
`rcflowed edges 78 to facilitate selective tungsten deposition
`in the contact hole 76. As is shown in FIG. 3d, tungsten is
`then selectively deposited into the contact hole 76 to form a
`tungsten butting contact 80 which is subsequently covered
`with a dummy metal layer 82 or connected to the metal layer.
`In the third embodiment, the second silicon nitride layer
`72 acts to thicken the first nitride layer 58 above the
`implanted regions 64,66 so as to cover any holes extending
`through the nitride which can be formed in the first nitride
`layer during the etching step to form the sidewall spacers.
`The second silicon nitride layer ensures that a sufficient
`thickness of silicon nitride remains after any etching in order
`to seal the interface with the gate oxide. The thickness of the
`first silicon nitride layer is, in both the second and third
`embodiments, selected so as to determine the required lateral
`spacing of the lightly doped region from the gate. However,
`when the spacing is small, the first silicon nitride layer may
`not be thick enough to prevent holes being formed therein
`during etching which extends down to the dielectric beneath.
`The use of a second silicon nitride layer as in the third
`embodiment overcomes this problem. In the third embodi-
`ment, the second silicon nitride layer also acts as a sealing
`layer adjacent the tungsten butting contact in the manner
`referred to hereinabove with reference to our earlier EP-A-
`0391562.
`
`A fourth embodiment of the present invention is illus-
`trated in FIGS. 4a to 4d. This embodiment is a modification
`of the third embodiment, the modification being the absence
`of the first silicon nitride layer which in the third embodi-
`ment is deposited over the polysilicon region and the gate
`oxide layer. In the fourth embodiment,
`the sequence of
`process steps up to the formation of side wall spacers and the
`formation of the lightly doped regions and the implanted
`regions adjacent the spacers is the same as that of the third
`embodiment except for the omission of the deposition of the
`silicon nitride layer. FIG. 4a shows the structure in which a
`gate oxide layer 94 is disposed on a silicon substrate 92 and
`a polysilicon region 96 is disposed on the gate oxide layer
`94. Side wall spacers 98,100 have been formed on opposed
`sides of the polysilicon region 96. Implanted regions 102,
`104 and lightly doped regions 106,108 are located in the
`silicon substrate 92 on respective opposed sides of the
`polysilicon region 96. Referring to FIG. 4b, a silicon nitride
`layer 110 is deposited over the polysilicon region 96, the
`side wall spacers 98,100 and the gate oxide layer 94.
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`Referring to FIG. 4c a dielectric layer 112 is then deposited
`over the silicon nitride layer 110 and subsequently densified.
`As is shown in FIG. 4d, a contact hole 114 is etched through
`the dielectric layer 112, the silicon nitride layer 110, the side
`wall spacer 100 and the gate oxide layer 94 so as to expose
`a portion of the polysilicon region 96 and, laterally adjacent
`thereto,
`the implanted region 104 and the lightly doped
`region 108. The etching may be performed in the manner
`described above with reference to the first embodiment. The
`dielectric material 112 is then reflowed to form reflowed
`edges 116 to facilitate selective tungsten deposition in the
`contact hole 114. Tungsten is then selectively deposited into
`the contact hole 114 to form a tungsten butting contact 118
`which is subsequently covered with a dummy metal layer
`120 or connected to a metal layer.
`The method and structure of the fourth embodiment are
`employed when it is not required laterally to space the
`lightly doped regions from the polysilicon gate.
`The semiconductor device and the process of the present
`invention have a number of advantages over the prior art.
`The tungsten butting contact for connecting the polysilicon
`and diffused silicon regions together may be formed utilising
`no extra process steps if the remainder of the semi-conductor
`device is fabricated employing conventional CMOS process
`steps and if the CMOS structure incorporates tungsten plugs
`for electrically connecting selected silicon regions to a metal
`interconnect layer overlying the dielectric layer. The contact
`hole for the tungsten butting contact may be formed simul-
`taneously with the contact holes for the other tungsten plugs
`and the tungsten can be deposited selectively in a single
`process step. In addition, the dummy metal pad may be
`deposited over the tungsten butting contact simultaneously
`with the formation of interconnect metal layer.
`The use of tungsten permits the butting contacts to be
`fabricated with the minimum lateral dimension, the lateral
`dimension being limited only by the photolithographic capa-
`bility of the process. This is because the tungsten butting
`contacts can be selectively deposited into substantially ver-
`tical contact holes.
`
`Furthermore, an advantage of using a refractory metal
`such as tungsten over aluminium is that the resultant butting
`contact has reduced lateral dimensions. When tungsten is
`employed to form the butting contact,
`the device lateral
`dimensions can be scaled down compared to those required
`for aluminium which requires either or both overlap of the
`Contact by aluminium on all sides to prevent etching of the
`contact during delineation of the interconnect pattern, and
`increased contact size at the top of the contact compared to
`its base in order to improve the metal step coverage. In
`addition, the high melting point and low silicon diffusion
`coeflicient of tungsten and other refractory metals results in
`those metals being superior to aluminium in multiple level
`metal interconnect systems.
`The present invention is not limited to the use of tungsten
`but can be carried out utilising any refractory metal which
`has low dopant diffusion therethrough and which preferably
`can be selectively deposited into a contact hole. Examples of
`such selectively depositable refractory metals are tungsten,
`copper, molybdenum and tantalum.
`What we claim is:
`1. A semiconductor device comprising a silicon substrate,
`an oxide layer on the silicon substrate, a doped polysilicon
`region disposed on the oxide layer, a dielectric layer which
`has been deposited over the doped polysilicon region and the
`silicon substrate, a contact hole which is formed in the
`dielectric layer and extends over respective laterally adja-
`
`
`
`5,541,434
`
`7
`cent portions of the doped polysilicon region and the silicon
`substrate, a refractory metal contact which has been selec-
`tively deposited in the Contact hole which electrically con-
`nects the said portions together, a first silicon nitride layer
`which covers that part of the doped polysilicon region which
`does not contact the contact, a side wall spacer which is
`disposed on the first silicon nitride layer adjacent a side of
`the doped polysilicon region in opposed relation to the
`contact and a second silicon nitride layer which covers the
`side wall spacer and the first silicon nitride layer.
`2. A semiconductor device according to claim 1 further
`comprising a metal capping layer which covers an upper
`surface of the contact and adjacent portions of an upper
`surface of the dielectric layer.
`3. A semiconductor device according to claim 1, wherein
`the side wall spacer and the contact are each located above
`a respective lightly doped implant region in the silicon
`substrate.
`4. A semiconductor device according to claim 1 wherein
`the doped polysilicon region and the portion of the silicon
`substrate are doped with dopants of opposite polarity.
`5. A semiconductor device according to claim 1 wherein
`the Contact is composed of tungsten.
`6. A semiconductor device comprising a silicon substrate,
`an oxide layer on the silicon substrate, a doped polysilicon
`region on the oxide layer, a dielectric layer over the doped
`polysilicon region and the oxide layer, a contact hole which
`is formed in the dielectric layer and extends over respective
`laterally adjacent portions of the doped polysilicon region
`and the silicon substrate, the doped polysilicon region and
`the portion of the silicon substrate being doped with dopants
`of opposite polarity, a tungsten contact which electrically
`connects the said portions together, a side wall spacer which
`is disposed on a first silicon nitride layer and adjacent a side
`
`10
`
`15
`
`20
`
`30
`
`8
`of the doped polysilicon region in opposed relation to the
`contact, and a second silicon nitride layer which covers the
`side wall spacer, the first silicon nitride layer over the doped
`polysilicon region, and those parts of the doped polysilicon
`region and of the silicon substrate other than said portions.
`7. A semiconductor device according to claim 6, wherein
`the side wall spacer and the contact are each located above
`a respective lightly doped implant region in the silicon
`substrate.
`8. A semiconductor device comprising a silicon substrate,
`a gate oxide layer on the silicon substrate, a doped polysili-
`con region on the gate oxide layer, a tungsten contact
`extending upwardly from and electrically connecting to
`laterally adjacent portions of the doped polysilicon region
`and the silicon substrate, a side wall spacer which is dis-
`posed on a first silicon nitride layer and adjacent a side of the
`doped polysilicon region in opposed relation to the contact,
`a second silicon nitride layer which covers the side wall
`spacer, the doped polysilicon region, the first silicon nitride
`layer over the doped polysilicon region, and respective parts
`of the silicon substrate adjacent to the side wall spacer and
`the tungsten contact, and a dielectric layer covering the
`second silicon nitride layer,
`the dielectric layer and the
`second silicon nitride layer defining a contact hole contain-
`ing the tungsten contact.
`9. A semiconductor device according to claim 8, wherein
`the side wall spacer and the contact are each located above
`a respective lightly doped implant region in the silicon
`substrate.
`10. A semiconductor device according to claim 8, wherein
`the doped polysilicon region and the portion of the silicon
`substrate are doped with dopants of opposite polarity.
`#1
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`*
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