`
`[19]
`
`[11] Patent Number:
`
`5,965,924
`
`Yen
`
`[45] Date of Patent:
`
`*Oct. 12, 1999
`
`US005965924A
`
`5,103,272
`5,202,279
`5245210
`5,286,674
`
`5’459’354
`,
`,
`
`5 541 434
`5:600:170
`
`[54] METAL PLUG LOCAL INTERCONNECT
`
`[75]
`
`Inventor: Ting P. Yen, Fremont, Calif.
`
`[*] Notice:
`
`[73] Assignee: Cypress Semiconductor Corp., San
`Jose’ Calif‘
`This. patent issued on a continued pros-
`e"““°“ aPP11°a“°“ filed under 37 CPR
`1~53(d), and is Subjecl 10 the IWCHIY Year
`patent
`term provisions of 35 U.S.C.
`154(,)(2).
`
`[21] Appl. No.: 08/900,047
`
`[22]
`
`Filed:
`
`Jul. 24, 1997
`
`Related U.S. Application Data
`
`[63] Continuation of application No. 08/561,951, Nov. 22, 1995,
`abandoned.
`
`Int. Cl.6 ........................... .. H01L 29/76; H01L 29/94
`[51]
`[52] U.S. Cl.
`257/383; 257/382; 257/388;
`257/903, 438/647; 438/649
`[58] Field of Search ................................... .. 257/382, 383,
`257/387, 388, 903; 437/190, 192; 438/647,
`649
`
`[56]
`
`References Cited
`U.S. PATENT DOCUMENTS
`
`4,566,175
`...................... .. 29/576
`1/1986 Smayling et al.
`4,746,219
`357/23.11
`5/1988 Holloway et al.
`
`.. 357/23.3
`4,878,100 10/1989 McDavid ..........
`........................... .. 437/192
`4,962,060 10/1990 Sliwa et al.
`............................ .. 437/52
`5,053,351
`10/1991 Fazan et al.
`
`4/1992 Nishiyama ............................ .. 257/388
`4/1993 Chung etal.
`437/47
`9/1993 Nishigoofi
`~ 257/383
`2/1994 Roth etal.
`437/190
`£<"i“°5>h-In
`10/1995 Hm Ha
`ara . . . . . . . .
`Eiggglfilét
`7/1996 Nicholls et al.
`2/1997 Sugiyama et al.
`
`. 257/383
`...................... 257/382
`
`FOREIGN PATENT DOCUMENTS
`2246369
`10/1990
`Japan ................................... .. 257/383
`0621372
`1/1994
`Japan ................................... .. 257/383
`OTHER PUBLICATIONS
`
`Silicon Processing For The VLSI Era, Vol. 2: Process
`Integration; Stanley olf, Ph.D.; pp. 144-145, 212-214, and
`354-355.
`
`Primary Examiner—Valencia Martin-Wallace
`Attorney, Agent, or Firm—Christopher P. Maiorana, P.C.
`
`ABSTRACT
`[57]
`A semiconductor structure that includes a silicon substrate
`
`which has a top surface, a diffusion region formed in the
`substrate adjacent
`to the top surface, a polysilicon gate
`formed on the top surface of the substrate adjacent to but not
`contacting the diifusion region, an insulator layer substan-
`tially covers the polysilicon gate and the diffusion region,
`the layer contains a via opening therein, and an electrically
`conducting plug filling at least partially the via opening
`providing electrical communication between the polysilicon
`gate and the diffusion region.
`
`17 Claims, 1 Drawing Sheet
`
`INTEL 100 1
`
`
`
`~~
`
`-
`
`-
`. .. ..
`
`257/754
`
`
`
`U.S. Patent
`
`Oct. 12, 1999
`
`5,965,924
`
`
`
`5,965,924
`
`1
`METAL PLUG LOCAL INTERCONNECT
`
`This is a Continuation of U.S. patent application Ser. No.
`08/561,951, filed Nov. 22, 1995 now abandoned.
`FIELD OF THE INVENTION
`
`The present invention generally relates to a metal plug
`local interconnect and a method of making the same, and
`more particularly, relates to a metal plug local interconnect
`which is formed in the same process of forming metal plugs
`that are already designed as sub-metal plugged contacts and
`a method of making the same.
`BACKGROUND OF THE INVENTION
`
`In the semiconductor fabrication process, it is frequently
`required to make local interconnect between a gate polysili-
`con layer to N+ and P+ diffusion regions. In the conventional
`art, this can be accomplished by using buried contacts to
`provide the necessary electrical connections. Aburied con-
`tact is formed by the physical contact of a polysilicon layer
`which is substantially polycrystalline silicon to a region
`doped by impurity ions in a semiconductor substrate. Buried
`contacts are most commonly used in a CMOS type of
`memory circuits.
`An enlarged top view and cross-sectional view of a
`conventional buried contact is shown in FIGS. 1A and 1B,
`respectively.
`In a typical fabrication process for buried
`contacts, a gate oxide layer (not shown) is first deposited on
`the surface of a silicon substrate 12. On top of the gate oxide
`layer, a thin layer of polysilicon (not shown) is then depos-
`ited to protect the gate oxide layer from contamination. The
`gate oxide layer and the polysilicon layer are then patterned
`by a photoresist masking process and etched. Openings (not
`shown) are formed on the surface of substrate 12 to expose
`sections of the substrate for the formation of buried contacts.
`
`An ion implantation process is performed at the openings to
`increase the surface dopant concentration for improved
`contact resistance. Subsequently,
`the photoresist layer is
`removed and a layer of polysilicon is deposited onto sub-
`strate 12. Thereafter, the polysilicon layer is patterned and
`etched, typically by a reactive ion etching method, to form
`a gate electrode 14 for making electrical connection with the
`diffusion region 16. Metal silicides may be used to reduce
`the resistivity of the polysilicon interconnect. The metal
`silicides offer the advantage of lower resistivity while retain-
`ing silicon gate characteristics. A BPSG planarization step
`completes the buried contact fabrication process.
`Electrical connection to the other diffusion region 18 can
`be made by metal contact 22 by first performing a contact
`masking and etching process. After the formation of the
`contact holes 24, a thin layer of titanium tungsten or titanium
`nitride is normally deposited into the contact hole to
`improve adhesion. Arefractory metal plug such as a tungsten
`plug is then deposited into hole 24. After a tungsten plug
`etch back process, a metal I layer 26 is deposited to provide
`connection to other devices.
`
`In order to make a local interconnect from a gate poly-
`silicon to both N+ and P+ diffusion regions by using a
`conventional buried contact, a complex set of processing
`steps must be added. This is because that gate polysilicon
`requires to be doped to both P+ and N+ depending on the
`diffusion doping the polysilicon is strapping to.
`Furthermore, in order to minimize inter-diffusion between
`N+ and P+ doping in polysilicon, additional processing steps
`are required to lower the diffusivity. This becomes more
`difficult as design rules are scaled down to the sub-micron
`range.
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`There are still other disadvantages of using a buried
`contact process. For instance, to avoid dopant penetration
`into the channel region, a P+ doped polysilicon needs to be
`implanted with the very low energy B11 instead of BF2 to
`avoid F+ enhanced dopant diffusion. This results in poor
`manufacturability. For a tungsten polycide process,
`the
`buried contact method does not allow an in—situ deposited
`and doped polysilicon/tungsten silicide structure. The buried
`contact method also makes it difficult to match the P+ doped
`and the N+ doped polycide sheet resistance in the case of a
`titanium silicide process.
`Other workers in the field of local interconnects have
`proposed methods to overcome the drawbacks and disad-
`vantages of the conventional buried contact process. One of
`such methods is to use a metallic local interconnect strap to
`shunt from a gate polysilicon to a diffusion region. Atypical
`process is shown in FIGS. 2A and 2B where an enlarged top
`view and cross-sectional view is shown, respectively. In a
`local interconnect strap method, a polysilicon gate 32 is first
`formed without direct contact with the diffusion regions 34
`and 36 in a silicon substrate 40. An insulating layer 42 of
`dielectric material is then deposited on top of the polysilicon
`and the diffusion regions. Vias are opened through masking/
`etching processes in the insulator layer 42. After the depo-
`sition of a glue layer (not shown), metal plugs 44, 46 and 48
`are deposited into the vias. After a tungsten plug etch back
`and a local interconnect masking/etching process, a local
`interconnect shunt layer 50 is deposited. A separate shunt 52
`is also deposited on metal plug 48 to allow the deposition of
`another metal plug 54 such that diffusion region 36 can be
`connected to the Metal I layer 56. The second metal plug 54
`is formed in a via opened in the second insulating layer 60
`of a dielectric material.
`
`The local interconnect strap method, even though accom-
`plishes the electrical connection between a polysilicon gate
`and a diffusion region, is a process-intensive method. For
`instance, it requires the additional processing steps of depos-
`iting an insulating layer between the local interconnect and
`the gate polysilicon, of opening vias in an insulating layer,
`of patterning and depositing the local interconnect layer.
`Moreover,
`from a topological standpoint,
`the process
`requires much larger layout area than a buried contact at the
`intersection of the gate polysilicon to the diffusion region.
`It is therefore an object of the present invention to provide
`a local interconnect between a polysilicon gate and a diffu-
`sion region that does not have the drawbacks and shortcom-
`ings of the prior art interconnect.
`It is another object of the present invention to provide a
`metal plug local interconnect for connecting a polysilicon
`gate to a diffusion region.
`It is a further object of the present invention to provide a
`metal plug interconnect between a polysilicon gate and a
`diffusion region that only requires a minimal number of
`additional processing steps.
`It is still another object of the present invention to provide
`a metal plug local interconnect that does not require the
`formation of a buried contacts.
`
`It is yet another object of the present invention to provide
`a metal plug local interconnect between a polysilicon gate
`and a diffusion region that does not require the use of a local
`interconnect strap.
`It is another further object of the present invention to
`provide a metal plug local interconnect between a polysili-
`con gate and a diffusion region wherein the metal plug local
`shunt can be formed in a single metal contact formation step.
`SUMMARY OF THE INVENTION
`
`In accordance with the present invention, a metal plug
`local interconnect between a polysilicon gate and a diffusion
`region and a method of making the same are provided.
`
`
`
`5,965,924
`
`3
`In a preferred embodiment, a semiconductor structure is
`provided which includes a silicon substrate having a top
`surface, a diffusion region formed in the substrate adjacent
`to the top surface, a polysilicon gate formed on the top
`surface of the substrate adjacent to but not contacting the
`diffusion region, an insulator layer which covers the poly-
`silicon gate and the diffusion region, the layer contains a via
`opening therein, and an electrically conducting plug filling
`at least partially the via opening to provide electrical con-
`nection between the polysilicon gate and the diffusion
`region.
`The present invention is further directed to a method of
`making a metal plug local interconnect in a semiconductor
`structure. The method includes the steps of first providing a
`silicon substrate that has a top surface,
`then forming a
`diffusion region in the substrate adjacent to the top surface,
`then forming a polysilicon gate on the top surface of the
`substrate adjacent to but not contacting the diffusion region,
`then depositing a layer of an insulating material on top of the
`polysilicon gate and the diffusion region, then forming a via
`in the layer of insulating material exposing at least a portion
`of the polysilicon gate and a portion of the diffusion region,
`and then depositing an electrically conducting material and
`filling at least partially the via opening such that the elec-
`trically conducting material contacts the polysilicon gate and
`the diifusion region and provides electrical communication
`therein between.
`
`BRIEF DESCRIPTION OF THE DRAWINGS
`
`FIGS. 1A and 1B show a top view and a cross-sectional
`view of a conventional buried contact.
`FIGS. 2A and 2B show a conventional buried contact
`process.
`
`FIGS. 3A and 3B show a top view and a cross-sectional
`view of a preferred embodiment of the present invention.
`
`DETAILED DESCRIPTION OF THE
`PREFERRED EMBODIMENT
`
`The present invention provides a semiconductor structure
`that has a metal plug local
`interconnect (or shunt) for
`connecting a polysilicon gate to a diffusion region in a
`structure and a method of forming such a semiconductor
`structure.
`
`Referring initially to FIGS. 3A and 3B wherein an
`enlarged top view and a cross-sectional view of the present
`invention metal plug local interconnect is shown, respec-
`tively. Diffusion regions 70 and 72 of either N+ or P+ doping
`are first formed by an ion implantation process in the surface
`of the silicon substrate 74. This is accomplished by pattern-
`ing through a photoresist layer and then etching to form
`openings for the diffusion regions for the ion implantation
`process. The photoresist layer is used as an implantation
`mask. The photoresist layer is then removed and polysilicon
`is deposited onto substrate 74. Thereafter, the polysilicon
`layer is patterned and etched by a reactive ion etching
`process to form gate electrode 74. This is shown in FIG. 3B.
`To form the present invention metal plug local intercon-
`nect for connecting polysilicon gate 74 to the diffusion
`region 70, an insulating layer 76 of silicon oxide is first
`deposited on top of the polysilicon gate 74 and the diffusion
`regions 70 and 72. In the same process of making sub-metal
`plugged contacts on the device, an additional via opening 78
`is provided for placing a metallic plug contact where the
`polysilicon gate is required to shunt to the diffusion region.
`A regular via opening 78 for a sub-metal plug contact is also
`
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`4
`formed during the same via opening process. After the vias
`76 and 78 are opened by a photoresist masking/etching
`process, a conducting metal is used to fill the via by a
`sputtering process. Any conducting metal can be used, even
`though refractory metals are preferred. For instance, refrac-
`tory metals of Ti, Ta and Mo are most frequently used. A
`metal plug local interconnect 80 thus formed interconnects
`the polysilicon gate at 82 and the diifusion region 70 at 84.
`Electrical contacts to both P+ and N+ diffusion regions can
`be achieved independent of the polysilicon doping. It should
`be noted that topologically, the present invention method
`does not require more layout area than a conventional buried
`contact method. Moreover, the present invention method
`requires substantially less layout area than a local intercon-
`nect strapping method. After a tungsten plug etch back
`process, a Metal I layer 84 is deposited with a glue layer 86
`in between the Metal I layer 84 and the metal plug 88.
`
`The present invention metal plug local interconnect can
`be fabricated in a process that has substantially lesser
`number of processing steps required than either a conven-
`tional buried contact process or a local interconnect strap-
`ping process. For instance, the present invention method
`saves 8~11 steps over a conventional buried contact process
`and saves 6~8 steps over a local interconnect strapping
`process. This is shown in the following process flow charts.
`
`Conventional Buried Contact Process
`
`thin poly deposition
`Step #1 -
`#2 - BC1 mask
`#3 - BC1 etch
`#4 -
`(BC implantation mask)
`#5 -
`(BC P+ implantation)
`#6 -
`(BC N+ implantation)
`#7 - Amorp Si deposition
`#8 - N+ Implantation
`#9 - P+ poly mask
`#10 - P+ poly implantation
`#11 - Si Recryst 8 hr+
`#12 - WSiX deposition
`#13 - Nit/BPSG
`STEP 14 THROUGH 21 NOT REQUIRED
`#22 - Contact mask/etch
`#23 - Glue deposition
`#24 - W-plug
`#25 - WEB
`#26 - Metal I
`TOTAL PROCESSING STEPS = 18
`
`Local Interconnect Strapping Process
`STEPS 1 THROUGH 11 NOT REQUIRED
`Step #12 - Insitu dope Poly/WSix
`#13 - Nit/BPSG (ILD1)
`#14 - Licon mask
`#15 - Licon etch
`#16 - Glue/LI deposition
`#17 -
`(W-plug)
`#18 —
`(WEB)
`#19 - Li mask
`#20 - Li etch
`#21 - ILD2 deposition
`#22 - Contact mask/etch
`#23 - Glue2 deposition
`#24 - W-deposition 2
`#25 - WEB2
`#26 - Metal I
`TOTAL PROCESSING STEPS = 15
`
`
`
`5,965,924
`
`6
`5. A semiconductor structure according to claim 1,
`wherein said electrically conducting plug is a refractory
`metal plug.
`6. A semiconductor structure according to claim 1,
`wherein said electrically conducting plug is formed of a
`material selected from the group consisting of titanium,
`tantalum, molybdenum and tungsten.
`7. A method of forming a local interconnect in a semi-
`conductor structure, comprising the step of:
`depositing an electrically conducting material in a via
`exposing at least a portion of a gate, a sidewall spacer
`adjacent to said gate and a portion of a diffusion region
`such that said electrically conducting material contacts
`and provides electrical communication between said
`gate and said diffusion region, said semiconductor
`structure comprising said diffusion region in a silicon
`substrate, said gate being on said substrate juxtaposed
`to but not contacting said diffusion region, said sidewall
`spacer being disposed above said diffusion region, said
`via being in an insulating material on said gate.
`8. A method according to claim 7, wherein said diffusion
`region is an N+ or a P+ region.
`9. A method according to claim 7, wherein said insulating
`material is selected from the group consisting of silicon
`oxide and silicon nitride.
`
`5
`
`Metal Plug Local Interconnect Process
`STEPS 1 THROUGH 11 NOT REQUIRED
`Step #12 - Insitu dope Poly/WSix
`#13 - Nit/BPSG
`STEPS 14 THROUGH 21 NOT REQUIRED
`#22 - Contact mask/etch
`#23 - Glue deposition
`#24 - W-plug
`#25 — WEB
`#26 - Metal I
`TOTAL PROCESSING STEPS = 7
`
`While the present invention has been described in an
`illustrative manner, it should be understood that the termi-
`nology used is intended to be in a nature of words of
`description rather than of limitation.
`invention has been
`Furthermore, while the present
`described in terms of a preferred embodiment thereof, it is
`to be appreciated that those skilled in the art will readily
`apply these teachings to other possible variations of the
`invention.
`The embodiments of the invention in which an exclusive
`property or privilege are defined as follows:
`I claim:
`
`1. A semiconductor structure comprising:
`a silicon substrate having a top surface,
`a diffusion region formed in said substrate adjacent to said
`top surface,
`a gate formed on the top surface of said substrate juxta-
`posed to but not contacting said diffusion region,
`a sidewall spacer adjacent to said gate and disposed above
`said diffusion region,
`an insulator layer substantially covering said gate and said
`diffusion region, and
`a conducting plug at least partially filling a via in said
`insulation layer that exposes said sidewall spacer in the
`absence of said conducting plug, said conducting plug
`providing direct electrical communication between said
`gate and said diffusion region.
`2. A semiconductor structure according to claim 1,
`wherein said diffusion region is an N+ or a P+ region.
`3. A semiconductor structure according to claim 1,
`wherein said insulator layer is formed of a material selected
`from the group consisting of silicon oxide and silicon
`nitride.
`
`4. A semiconductor structure according to claim 1,
`wherein said electrically conducting plug is a metal plug.
`
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`*
`
`10. A method according to claim 7, wherein said electri-
`cally conducting plug is a metal plug.
`11. A method according to claim 7, wherein said electri-
`cally conducting plug is preferably a refractory metal plug.
`12. A method according to claim 7, wherein said electri-
`cally conducting plug is formed of a material selected from
`the group consisting of titanium, tantalum, molybdenum and
`tungsten.
`13. A semiconductor structure according to claim 1,
`wherein said conducting plug comprises an outer glue layer
`and a plug material therein.
`14. A semiconductor structure according to claim 1,
`wherein said polysilicon gate and said diffusion region being
`exposed in said via in the absence of said conducting plug.
`15. A method according to claim 7, wherein said gate is
`a polysilicon gate.
`16. The structure according to claim 1, wherein said gate
`comprises polysilicon.
`17. The method according to claim 7, wherein said gate
`comprises polysilicon.
`*
`
`*
`
`*
`
`*