`US 6,228,777 B1
`(10) Patent No.:
`(12)
`Arafa etal.
`(45) Date of Patent:
`May8, 2001
`
`
`US006228777B1
`
`(54)
`
`(75)
`
`INTEGRATED CIRCUIT WITH
`BORDERLESS CONTACTS
`
`Inventors: Mohamed Arafa, Hillsboro; Scott
`Thompson,Portland, both of OR (US)
`Intel Corporation, Santa Clara, CA
`
`(73) Assignee:
`
`(*) Notice:
`
`US(US)
`Subject to any disclaimer, the term ofthis
`patent is extended or adjusted under 35
`US.C. 154(b) by 0 days.
`
`(21) Appl. No.: 09/328,190
`(22)
`Filed:
`Jun. 8, 1999
`
`(56)
`
`438/675
`
`7
`Tint, Cd ie eesecssecseccneeeneeseesente HO1L 21/302
`(51)
`(52) U.S. Cl].
`ccccccccccccscssssssccsccessscssesenseee 438/740; 438/740
`(58) Field of Search 0... 438/664, 666,
`438/683, 674, 704, 740, 970, 634, 675,
`655, 221, 437, 291, 910
`.
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`Primary Examiner—David Nelms
`Assistant Examiner—David Nhu
`(74) Attorney, Agent, or Firm—Mark Seeley
`67)
`ABSTRACT
`An integrated circuit comprising a conductive region formed
`.
`w.
`on a semiconductor substrate, a silicate glass layer formed
`:
`:
`on the conductive region, and an etch stop layer formed on
`the silicate glass layer. The integrated circuit also includes a
`borderless contact that is coupled to the conductive region.
`
`10 Claims, 3 Drawing Sheets
`
`ESsss
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`N
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`NNNNNNNN
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`NSk
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`TSMC 1317
`TSMC1317
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`US 6,228,777 B1
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`Page 2
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`CVD Si02 Films”, Proceedings Ninth International VLSI
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`N.Stojadinovic, S. Dimitrijev, “Instabilities in MOS Tran-
`sistors”, Microelectrones and Relibility, 1989, vol. 29, No. 3
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`K. Shmokawa, T. Usami, S. Tokitou, N. Hirashita, M.
`Yoshimaru, M. Ino, “Supression of the MoS Transistor Hot
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`metal Dielectric”, IEEE Symposium on VLSI Technology
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`AN. Saxena, K Ramkumar, S.K. Ghosh,“Stresses in TEOS
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`V. Jain, D. Praminik, “Impact of Inter Metal Oxide Struc-
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`Interconnection Conference
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`N. Shimoyama, K. Machida, K. Murase, T. Tsuchiya,
`“Enhanced Hot—Carrier Degradation Due to Water in TEOS/
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`
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`
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`Devices”, IEEE Transactions Reliability, 8/83 pp. 323-329.
`
`* cited by examiner
`
`
`
`U.S. Patent
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`Sheet 1 of 3
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`May8, 2001
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`US 6,228,777 B1
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`FIGURE 2
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`
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`U.S. Patent
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`May8, 2001
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`Sheet 2 of 3
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`US 6,228,777 B1
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`
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`FIGURE 3
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`U.S. Patent
`
`May8, 2001
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`Sheet 3 of 3
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`US 6,228,777 B1
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`
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`FIGURE 4
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`US 6,228,777 B1
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`2
`1
`FIG. 2 is an illustration of a cross-section of the device
`INTEGRATED CIRCUIT WITH
`BORDERLESS CONTACTS
`shown in FIG. 1 that includes a silicate glass layer formed
`onasilicide.
`FIELD OF THE INVENTION
`FIG. 3 is an illustration of a cross-section of the device
`shown in FIG. 2 that includes an etch stop layer formed on
`the silicate glass layer.
`FIG. 4 is an illustration of a cross-section representing an
`embodiment of the integrated circuit of the present inven-
`tion.
`
`The present invention relates to integrated circuits and a
`method for making them.
`BACKGROUND OF THE INVENTION
`
`DETAILED DESCRIPTION OF THE PRESENT
`INVENTION
`
`To continue adding transistors to integrated circuits with-
`out significantly increasing die sizes, the distance between
`transistors and other devices may have to be reduced. The
`need to reduce the distance between devices may require
`reducing the width of the landing area for the contacts. As
`An improved integrated circuit and method for makingit
`a result, when contact is madeto the landing area, part of the
`are described. FIG. 1 illustrates a device 100 that may be
`contact may extend laterally over the isolation structure,
`made using conventional process steps for forming an
`forming a borderless contact. To prevent the contact etch
`integrated circuit. Device 100 represents a structure that may
`step from etching into the isolation structure, an etch stop
`be used to form an MOStransistor, and includes well 149
`layer may be formed on the surface of the device prior to
`upon which is formed gate oxide 101 and gate 102. As
`performing the contact etch. Such a layer may comprise
`silicon nitride.
`shown, gate 102 comprises polysilicon 146 andsilicide 148.
`On the sides of gate 102 is oxide 103, which serves as a
`In conventional devices, which do not include borderless
`stress buffer for the nitride layer used to form nitride spacers
`contacts, an interlayer dielectric (“ILD”) that includes a
`104. On either side of spacers 104 are conductive regions
`silicon dioxide, PSG, or BPSG layeris frequently formed on
`130 and 131, which are formed on well 149. In this embodi-
`a silicide. The presenceofthat layer, and the processes used
`ment of the present invention, conductive regions 130 and
`to deposit and etch it, give the resulting device certain
`131 comprise suicides 105 and 106, which rest on diffused
`properties. Whenasilicon nitride layer is formed between
`25
`the silicide and such an ILD layer, for enabling borderless regions 107 and 108, respectively. Also shown in FIG.1is
`
`contacts, the silicon nitride layer (and processes used to form
`shallow trench isolation structure 109 formed adjacent to
`well 149.
`and etch it) may cause the resulting device’s characteristics
`to differ from those of a device that lacks such a layer.
`Someof those changes may be undesirable. For example,
`adding such a silicon nitride layer may introduce certain
`stresses that can degrade the saturation current or cause the
`device’s threshold voltage to shift. Depositing a silicon
`nitride layer directly on top of a silicide may increase the
`silicide’s sheet resistance and adversely affect the way the
`silicide agglomerates. When using a plasma process to
`remove silicon nitride, different charging characteristics
`may result, when comparedto those that result when etching
`the ILD layer. Also, when such a silicon nitride etch stop
`layeris deposited using a hot wall chemical vapor deposition
`(“CVD”) process, significant portions of the silicide may
`oxidize.
`
`Well 149 may be a heavily doped (e.g., p+ or n+) p-well
`or n-well, depending upon whether the device formed above
`well 149 is an n-MOS or p-MOSdevice. Gate oxide 101,
`gate 102, oxide 103, nitride spacers 104, suicides 105 and
`106 and diffused regions 107 and 108 may be made from
`materials conventionally used to form suchstructures using
`conventional process steps, as is well understood by those
`skilled in the art.
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`Although conductive regions 130 and 131 shownin FIG.
`1 include suicides 105 and 106 formed on diffused regions
`107 and 108, any conductive structure or material that may
`receive a borderless contact may comprise a conductive
`region, as that term is used herein. The term “conductive
`region” is thus not intended to be limited to the structure
`shown in FIG. 1.
`
`Accordingly, there is a need for a method for making a
`device having borderless contacts that mitigates against the
`Shallow trench isolation structure 109 may comprise a
`type of device characteristic changes and performance deg-
`combination of grown and deposited oxide and may be
`radation that the silicon nitride etch stop layer may cause. In
`formed in numerous ways, such as using the process
`particular, there is a need for a device that is not adversely
`described in U.S. Pat. No. 5,719,085, assigned to this
`affected by stresses, unwanted changesto silicide properties,
`application’s assignee.
`or undesirable charging effects, which may result from
`When making one embodimentof the integrated circuit of
`forming such a layer. There is also a need for a process for
`50
`the present invention,relatively thin silicate glass layer 111
`makinga device that includes suchasilicon nitride layer that
`is formed on the surface of device 100, as shown in FIG. 2.
`permits use of a hot wall CVD process to deposit such a
`Preferably, layer 111 is between about 100 and about 1,000
`layer, without causing significant oxidation ofthe silicide.
`angstroms thick, and more preferably between about 200
`SUMMARYOF THE INVENTION
`and about 400 angstromsthick.
`Silicate glass layer 111 may comprise an undoped silicon
`dioxide, phosphosilicate glass (PSG) or borophosphosilicate
`glass (BSPG) layer. Such a layer may be formed on the
`surface of device 100 by applying a conventional plasma
`enhanced CVD (PECVD), atmospheric pressure CVD
`(APCVD) or
`low pressure CVD (LPCVD) process.
`Preferably, layer 111 comprises silicon dioxide deposited
`onto the surface of device 100 using a PECVD process,
`which employs conventional equipment and materials, e.g.,
`silane, tetraethylorthosilicate (TEOS), or someothersilicon
`source.
`
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`65
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`The present invention covers an integrated circuit com-
`prising a conductive region formed on a semiconductor
`substrate, a silicate glass layer formed on the conductive
`region, and an etch stop layer formed on the silicate glass
`layer. The integrated circuit also includes a borderless con-
`tact that is coupled to the conductive region. The present
`invention further covers a method for forming such an
`integrated circuit.
`BRIEF DESCRIPTION OF THE DRAWINGS
`FIG. 1. is an illustration of a cross-section of a device that
`may be formed when making an embodiment of the inte-
`grated circuit of the present invention.
`
`After formingsilicate glass layer 111, etch stop layer 120
`is formed on silicate glass layer 111, as shown in FIG. 3.
`
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`US 6,228,777 B1
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`4
`the contact, a two step process may be used instead, where
`the first step etches through ILD layer 125 and the second
`step etches through both silicon nitride layer 120 andsilicate
`glass layer 111.
`After the via has been etched through layers 125, 120 and
`111, borderless contact 110 is formed to make electrical
`contact to conductive region 130, e.g., by contacting silicide
`105, as shown in FIG. 4. Borderless contact 110 is formed
`by filling the via with a conductive material. As shown in
`FIG. 4, that conductive material may comprise relatively
`thin titantum and titanium nitride layers 119 and 118 and
`tungsten plug 117, which are successively deposited to fill
`the via.
`
`3
`Layer 120 preferably comprises silicon nitride, which may
`be deposited onto silicate glass layer 111 using conventional
`techniques for forminga silicon nitride layer, some of which
`are described in U.S. Pat. No. 5,633,202, assigned to this
`application’s assignee. In this embodiment of the present
`invention, layer 120 preferably is between about 100 and
`about 1,500 angstroms thick, and more preferably between
`about 200 and about 500 angstromsthick.
`When made from silicon nitride, layer 120 may be formed
`using a hot wall LPCVD or a PECVD process. When the hot
`wall process is used, dichlorosilane and ammonia may be
`fed into the reactor at a temperature that
`is preferably
`between about 550 and about 800° C. Such a hot wall
`process is preferred to a PECVD process for depositing
`Formingsilicate glass layer 111 betweensilicide 105 and
`silicon nitride as the resulting layer should provide more
`silicon nitride layer 120 may provide a numberof advan-
`favorable selectivity, uniformity and quality. Unlike a
`tages over processes that deposit a silicon nitride layer
`PECVD process, a LPCVD process should not produce
`directly on the silicide. Silicate glass layer 111 acts as a
`undesirable charging effects. In addition, because such an
`stress reliever, which should reduce the shift
`in device
`LPCVDprocess is a batch process, such a process may
`characteristics that the silicon nitride layer may otherwise
`provide higher throughput than a PECVD process.
`cause. Devices that include such a layer may also show
`reduced variance in resistance in both the silicide and the
`After etch stop layer 120 is deposited, ILD layer 125 is
`contacts, and may be morereliable. In addition, the presence
`formed.
`ILD layer 125 may be formed from the same
`of such a silicate glass layer may decrease the amount of
`insulating material used to form silicate glass layer 111 using
`silicide degradation and adverse charging effects, which
`the same equipmentand similar process steps, but modified
`otherwise may result from the silicon nitride etch step.
`to produce a layer that is between about 3,000 and about
`Formingasilicate glass layer between the silicide and the
`10,000 angstroms thick. Alternatively, ILD layer 125 and
`silicon nitride layer may thus enable selection of a silicon
`layer 111 may be formed from different materials.
`nitride etch process without having to considerthe effect that
`Preferably, ILD layer 125 is a PSG layer formed using a
`such a process may have onsilicide degradation or device
`PECVDprocess that employs TEOS—although other CVD
`charging.
`processes, which use other silicon sources, may be used.
`Although ILD layer 125 preferably is a PSG layer, ILD layer
`Another advantage of this new process is that silicon
`125 could instead comprise a silicon dioxide or BPSG layer
`nitride layer 120 may be formed using a hot wall CVD
`or be formed from other materials that may provide an
`process instead of a PECVD process, because silicon glass
`insulating function. When a PSG layer,
`the phosphorus
`layer 111 may protect the silicide from oxygen used in such
`source may be phosphine, diphosphide or trimethylphos-
`a process. Such a relatively high temperature hot wall
`phide. When a BPSG layer,
`the boron source may be
`process may produce a higher quality furnace nitride, with
`diborane or trimethylborate.
`improved uniformity, than may be producedbya relatively
`low temperature PECVD process. In addition, such a hot
`Following deposition of ILD layer 125, that layer may be
`wall process should not generate potentially troublesome
`planarized, such as by applying a chemical mechanical
`charging effects that a PECVD process may produce.
`polishing step. A layer of oxide (not shown) may then be
`Features shownin the above referenced drawings are not
`deposited on top of ILD layer 125, e.g., by using TEOS in
`intended to be drawnto scale, nor are they intended to be
`a PECVDprocess.
`shown in precise positional relationship. For example, bor-
`After the dielectric layer or layers have been formed on
`derless contact 110 could be formed further to the right from
`etch stop layer 120, a three step etch may be performed to
`the position shown in FIG. 4 and the relative thickness of
`etch the via for the contact through ILD layer 125, etch layer
`layer 111 to layer 120 may vary from what is shown in the
`120, and silicate glass layer 111. A single wafer,
`low
`figures. Additional process steps that may be used to make
`frequency, parallel plate etcher may be used. The etch
`the embodiments described above have been omitted when
`chemistry preferably employs Freon gases, e.g., CHF3, CF,,
`not useful to describe aspects of the present invention.
`C.F, as the active species. The etch chemistry may also
`Although the foregoing description has specified an inte-
`include conventionally used amounts of argon and oxygen
`grated circuit that includes certain features, and has specified
`and/or nitrogen. By using an etch chemistry that has high
`certain materials and process steps for making such an
`etch selectivity for the material used to make ILD layer 125,
`integrated circuit, those skilled in the art will appreciate that
`when comparedto the selectivity of silicon nitride layer 120,
`many modifications and substitutions may be made.
`layer 120 mayact as an etch stop preventing that etch step
`Accordingly,
`it
`is intended that all such modifications,
`from reaching shallow trench isolation region 109.
`alterations, substitutions and additions be considered to fall
`After ILD layer 125 is etched,silicon nitride layer 120 is
`within the spirit and scope of the invention as defined by the
`etched. Silicon nitride layer 120 may be etched using the
`appended claims.
`same equipmentused to etch ILD layer 125, but employing
`Whatis claimedis:
`an etch chemistry having a high selectivity to silicon nitride,
`when compared to the selectivity of the material used to
`make layer 111. After layer 120 is etched,silicate glass layer
`111 is etched. Silicate glass layer 111 may be etched using
`the same equipment and etch chemistry used to etch ILD
`layer 125, while modifying the process to account for the
`differences in thickness between those two layers. Although
`a three step etch process is preferred for making the via for
`
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`1. A method for forming an integrated circuit comprising:
`forming a conductive region on a semiconductor sub-
`strate;
`forming a silicate glass layer on the conductive region;
`forming an etch stop layer on the silicate glass layer; and
`forming a borderless contact coupled to the conductive
`region by etching through the etch stop layer,
`then
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`US 6,228,777 B1
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`8. The method of claim 7 wherein the undoped silicon
`dioxide layer formed on the conductive region is between
`about 200 and about 400 angstroms thick, and the silicon
`nitride layer is between about 200 and about 500 angstroms
`thick.
`
`6
`forming a silicon nitride layer on the undoped silicon
`dioxide layer;
`forming a PSG layer on the silicon nitride layer; and
`forming a borderless contact coupled to the conductive
`region by etching through the siliconnitride layer, then
`etching through the undoped silicon dioxide layer to
`form a via,
`then filling the via with a conductive
`material.
`
`5
`etching through the silicate glass layer to form a via,
`then filling the via with a conductive material.
`2. The method of claim 1 wherein thesilicate glass layer
`comprises a silicon dioxide layer; and the etch stop layer
`comprises silicon nitride, and further comprising forming a
`phosphosilicate glass (PSG) layer on the silicon nitride
`layer.
`3. The method of claim 2 wherein the borderless contact
`is formed by etching a via through the PSG layer, the silicon
`nitride layer, and the silicon dioxidelayer, then filling the via
`with a conductive material.
`4. The method of claim 3 wherein the silicon nitride layer
`is formed using a hot wall chemical vapor deposition
`process.
`9. The method of claim 8 wherein the silicon nitride layer
`5. The method of claim 4 wherein the via is etched
`is formed using a hot wall chemical vapor deposition
`through the PSG layer,
`the silicon nitride layer, and the
`process and the silicon dioxide and PSG layers are both
`silicon dioxide layer in three separate etching steps.
`formed using a plasma enhanced chemical vapor deposition
`6. The method of claim 5 wherein the borderless contact
`process.
`is formed by successively depositing in the via relatively
`10. The method of claim 9 further comprising etching a
`thin titantum and titanium nitride layers and a relatively
`via through the PSG layer, the silicon nitride layer, and the
`thick tungsten plug.
`silicon dioxide layer in three separate etch steps,
`then
`7. Amethodfor forming an integrated circuit comprising:
`successively depositing in the via relatively thin titantum
`forming a conductive region on a semiconductor sub-
`and titanium nitride layers andarelatively thick tungsten
`strate;
`plug.
`25
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`
`forming an undopedsilicon dioxide layer on the conduc-
`tive region;
`
`
`
`PATENT NO.—: 6,228,777 BI Page | of |
`
`
`DATED
`: May 8, 2001
`INVENTOR(S): Arafa et al.
`
`It is certified that error appears in the above-identified patent and that said Letters Patentis
`hereby corrected as shown below:
`
`Column 2
`Line 24, delete "suicides" and insert -- silicides --,
`Line 32, delete "suicides" and insert -- silicides --.
`
`UNITED STATES PATENT AND TRADEMARK OFFICE
`CERTIFICATE OF CORRECTION
`
`Director of the United States Patent and Trademark Office
`
`Signed and Sealedthis
`
`Seventh Day of May, 2002
`
`JAMES E. ROGAN
`
`Attest:
`
`Attesting Officer
`
`