`U8005869902A
`
`[19]
`United States Patent
`5,869,902
`[11] Patent Number:
`[45] Date of Patent: *Feb. 9, 1999
`Lee et al.
`
`
`
`[54] SEMICONDUCTOR DEVICE AND
`MANUFACTURING METHOD THEREOF
`
`[75]
`
`Inventors: Sang-in Lee; Chang-sou Park, both of
`Kyungki-do, Rep. of Korea
`
`[73] Assigneez' Samsung Electronics Co., Ltd.,
`Kyungki—Do, Rep. of Korea
`
`[*] Notice:
`
`The term of this patent shall not extend
`beyond the expiration date of Pat. No.
`5,355,020.
`
`[21] App1.No.: 612,792
`
`[22]
`
`Filed:
`
`Mar.11, 1996
`
`Related US. Application Data
`
`[60] Division of Ser. No. 8,775, Jan. 25, 1993, Pat. No. 5,534,
`463, which is a continuation-in—part of Ser. No. 897,294,
`May 11, 1992, Pat. No. 5,318,923, which is a continuation—
`in-part of Ser. No. 585,218, Sep. 19, 1990, abandoned.
`
`Foreign Application Priority Data
`[30]
`Jan. 23, 1992
`[KR]
`Rep. of Korea
`
`92-904
`
`[51]
`
`Int. Cl.‘5
`
`H01L 23/48; H01L 2.3/52;
`H01L 29/40
`.......... 257/773; 257/751; 257/752;
`[52] US. Cl.
`257/758, 2 7/763; 257/764; 257/765; 257/767;
`257/770; 257/774; 257/775
`[58] Field of Search ................................... .. 257/751, 752,
`
`257/758,
`3, 764, 765, 767, 770, 771,
`774, 775
`
`
`
`[56]
`
`References Cited
`U.S. PATENT DOCUMENTS
`
`
`
`5/1986 Anderson
`4,589,196
`4,630,357 12/1986 Rogers et al.
`4,641,420
`2/1987 Lee .
`4,720,908
`1/1988 Wills ..................................... .. 437/192
`4,963,511
`10/1990 Smith ..
`437/192
`
`
`4,970,176 11/1990 Tracy et a1
`437/187
`1/1991 Arima etal. ............................ 437/246
`4,983,547
`
`148/DIG. 20
`437/195
`
`FOREIGN PATENT DOCUMENTS
`
`8/1986
`61-183942
`5/1987
`62-109341
`6/1987
`62—132348
`9/1987
`62—211915
`62-274640 11/1987
`
`Japan .
`Japan .
`Japan .
`Japan .
`Japan ..................................... 437/195
`
`(List continued on next page.)
`OTHER PUBLICATIONS
`
`W.Y—C Lai, et al., “CVD Aluminum for Submicro—VLSI
`Metallization” 1991 Proc. 8th International Conference
`(Jun. 11—12, 1991) pp. 89—95.
`Hisako Ono et al., “Development of a Planarzdie Al—Si
`Contact Filling Technology”, VMIC Conference, Jun. 12,
`1990, pp. 76—82.
`
`(List continued on next page.)
`
`
`Primary Examiner—Mahshid D. Saadat
`Assistant Examiner
`Jhihan B. Clark
`Attorney, Agent, or Firm—Pillsbury Madison & Sutro LLP
`
`[57]
`
`ABSTRACT
`
`A wiring layer of a semiconductor device having a novel
`contact structure is disclosed. The semiconductor device
`
`includes a semiconductor substrate, an insulating layer hav-
`ing an opening (contact hole or via), a reactive spacer
`formed on the sidewall of the opening or a reactive layer
`formed on the sidewall and on the bottom surface of the
`opening and a first conductive layer formed on the insulating
`layer which completely fills the opening. Since the reactive
`spacer or layer is formed on the sidewall of the opening,
`when the first conductive layer material is deposited, large
`islands will form to become large grains of the sputtered Al
`film. Also, providing the reactive spacer or layer improves
`the reflow of the first conductive layer during a heat-treating
`step for filling the opening at a high temperature below a
`melting temperature. Thus, complete filling of the opening
`with sputtered Al can be ensured. All the contact holes, being
`less than 1 pm in size and having an aspect ratio greater than
`1.0, can be completely filled with Al, to thereby enhance the
`reliability of the wiring of a semiconductor device.
`
`(List continued on next page.)
`
`38 Claims, 9 Drawing Sheets
`
`96
`
`
`
`
`7......lm
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`I...
`21
`
`
`
`
`Page 1 of 23
`
`TSMC Exhibit 1027
`
`TSMC v. lP Bridge
`lPR2016-01249 & IPR2016-01264
`
`Page 1 of 23
`
`
`
`5,869,902
`
`Page 2
`
`U.S. PATENT DOCUMENTS
`
`OTHER PUBLICATIONS
`
`12/1991 Inoue et a1.
`............................. 437/203
`5,071,791
`
`:1‘911 ft lal-
`eee a.
`,
`,
`5/1994 Hindman et al.
`5,317,187
`7/1996 Lee ctal.
`5,534,463
`
`12/1996 Lee et a1.
`5,589,713
`FOREIGN PATENT DOCUMENTS
`
`257/659
`437/195
`257/773
`
`63-99546
`1-246831
`2~26052
`90—15277
`
`4/1988
`10/1989
`1/1990
`3/1989
`
`Japan .
`Japan .
`Japan .
`Rep. of Korea .
`
`Dipankar Pramanik at 31., “Efiec[ of Underlayer 0n Spu[_
`tered Aluminum Grain Structure and Its Correlation with
`.
`-
`~
`V-
`n V
`.
`.
`if:Eggerdgeggzfigfincmn las ’ M1C conference’ Jun
`’
`’pp‘
`“
`‘
`.
`.
`.
`C-s‘ Park 61 31-, Al—PlaPh (Alummumrplanamauon by
`Post—Heating) Process for Planarized Double Metal CMOS
`Applications”, VMIC Conference,
`Jun. 12, 1991, pp.
`326—328.
`
`H.P. Kattelus et a1., “Bias—induced Stress Transitions in
`Sputtered TiN Films”, J. Vac Sci. Technol. v01. 4, Jul/Aug.
`1986, pp. 1850—1854.
`
`Page 2 0f 23
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`Page 2 of 23
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`US. Patent
`
`Feb. 9,1999
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`Sheet 1 0f9
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`5,869,902
`
`FIG.1 (PRIOR ART)
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`Page 3 0f 23
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`US. Patent
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`Feb. 9, 1999
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`Sheet 3 0f9
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`5,869,902
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`Feb. 9, 1999
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`US. Patent
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`Feb. 9, 1999
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`Sheet 5 0f 9
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`5,869,902
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`Feb. 9’ 1999
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`Feb. 9, 1999
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`Sheet 9 of 9
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`5,869,902
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`5,869,902
`
`1
`SEMICONDUCTOR DEVICE AND
`MANUFACTURING METHOD THEREOF
`
`This is a division of application Ser. No. 08/008,775,
`filed Jan. 25, 1993 which is now US. Pat. No. 5,534,463
`which is a continuation in part of application Ser. No.
`07/897,294 , May 11, 1992, now US. Pat. No. 5,318,923.
`
`BACKGROUND OF THE INVENTION
`
`The present invention relates to a semiconductor device
`and manufacturing method thereof, and more particularly to
`a semiconductor device including a wiring layer and method
`for forming a wiring layer. The present
`invention is an
`improvement over the invention which is the subject matter
`of the present inventor’s US. Pat. No. 5,318,923 filed on
`Aug. 24, 1992 which is a continuation-in—part of the US.
`patent application Ser. No. 07/585,218 filed on Sep. 19,
`1990, which has now been abandoned, and the disclosure of
`which is hereby incorporated into this application by refer-
`ence.
`
`The metallization process is regarded as being the most
`important matter of semiconductor device manufacturing
`technology, since it determines the yield, performance (e.g.,
`speed of operation), and reliability of the devices, as the
`technology advances toward ultra large-scale integration
`(ULSI). Metal step coverage was not a serious problem in
`less dense prior art semiconductor devices, because of the
`inherent features of devices having larger geometries, e.g.,
`contact holes having low aspect ratios (the ratio of depth to
`width), and shallow steps. However, with increased integra-
`tion density in semiconductor devices, contact holes have
`become significantly smaller while impurity-doped regions
`formed in the surface of the semiconductor substrate have
`become much shallower. Due to the resulting higher aspect
`ratio of the contact holes and larger steps, with these current,
`greater-density semiconductor devices,
`it has become
`necessary, to improve the conventional aluminum (Al) met-
`allization process, in order to achieve the standard design
`objectives of high-speed performance, high yield, and good
`reliability of the semiconductor device. More particularly,
`the utilization of the conventional Al metallization process
`in the fabrication of the higher-density integrated semicon-
`ductor devices has resulted in such problems as degraded
`reliability and failure of the Al interconnections due to the
`high aspect ratio of the contact holes and poor step coverage
`of the sputtered Al, increase in contact resistance caused by
`silicon (Si) precipitation, and degradation of the shallow
`junction characteristics due to Al spiking.
`FIG. 1 illustrates a cross—sectional view of a portion of a
`semiconductor wafer having a metal wiring layer formed
`thereon obtained according to a prior art method, which
`illustrates a void formation. Referring to FIG. 1, an insulat-
`ing layer 5 is formed on a semiconductor substrate 1. Then,
`a contact hole having a high aspect ratio greater than one,
`which exposes an impurity-doped region 3 formed in a
`surface portion of semiconductor substrate 1, is formed in an
`insulating layer 5 and on impurity-doped region 3.
`Thereafter, a diifusion barrier layer 7 is formed on insulation
`layer 5, on the inner surface of the contact hole and on the
`exposed surface portion of impurity-doped region 3, and a
`metal layer 911 is deposited by a conventional sputtering
`method. Here, due to the high aspect ratio of the contact
`hole, an overhanging portion 15 of the deposited metal layer
`9a is formed over the contact hole and a void 11a formation
`occur in the contact hole, which deteriorates the reliability of
`metal layer 9a of a semiconductor device.
`
`10
`
`20
`
`30
`
`40
`
`50
`
`60
`
`2
`In an effort to overcome these problems of the conven-
`tional Al metallization process, various new processes have
`been proposed. For example, for preventing degraded semi-
`conductor reliability caused by the above-mentioned failure
`of Al interconnections, the following processes have been
`proposed.
`Melting methods have been disclosed in such patent
`publications such as Japanese Laid-Open Publication No.
`62—132348 (by Yukiyasu Sugano et al.), Japanese Laid-Open
`Publication No. 63-99546 (by Shinpei Iijima), Japanese
`Laid-Open Publication No. 62-109341 (by Masahiro
`Shimizu et al.), Japanese Laid-Open Publication No.
`62-211915 (by Hidekazu Okabayashi et al.), Japanese Laid-
`Open Publication No.1—246831 (by Seiichi Iwamatsu), Japa-
`nese Laid-Open Publication No. 59-171374 (by Masaki
`Satou) and European Patent Application No. 873060843
`(by Ryoichi Mukai et al.). Particularly, according to Yuki-
`yasu Sugano et a1 teaching, a metal wiring layer comprised
`of a metal having a low melting temperature such as Al, Sn,
`In, Pb, Mg, Zn etc. or an alloy thereof is melted thermally,
`to thereby be flattened.
`According to the above method, the contact hole is filled
`by means of melting and refiowing Al or an Al alloy. To
`summarize, in the reflowing step, the metal layer of Al or Al
`alloy is heated beyond its melting temperature, and the thus
`melted metal is flowed into the contact hole to fill the same.
`This reflowing step entails the following drawbacks and
`disadvantages. First of all, the semiconductor wafer must be
`disposed horizontally so as to allow proper filling of the
`contact hole with the flowing melted material. Secondly, the
`liquid metal layer flowed into the contact hole will seek a
`lower surface tension, and thus, may, upon solidifying,
`shrink or warp, and thereby expose the underlying semicon-
`ductor material. Further,
`the heat
`treatment
`temperature
`cannot be precisely controlled and therefore, given results
`are difficult to reproduce. Moreover, although these methods
`may fill a contact hole with the melted metal of the metal
`layer, the remaining areas of the metal layer (outside the
`contact hole area) may become rough,
`thereby impairing
`subsequent photolithography processes. Therefore, a second
`metallization process may be required to smooth or pla-
`narize these rough areas of the metal layer.
`In the meantime, Ono et al. have disclosed that when the
`semiconductor substrate temperature is above 500° C., the
`liquidity of Al—Si suddenly increases (in Proc., 1990 VMIC
`Conference, June 11 and 12, pp. 76—82). According to this
`paper, the stress of an Al-1%Si film changes abruptly near
`500° C., and the stress relaxation of such a film occurs
`rapidly at that temperature. Additionally, the temperature of
`the semiconductor substrate must be maintained between
`500° C. and 550° C.
`in order to fill
`the contact holes
`satisfactorily.
`Additionally, Yoda Dakashi et al. have suggested a
`method for manufacturing a semiconductor device which
`comprises the steps of forming double barrier layers for
`preventing a reaction between the wiring layer and the
`semiconductor substrate or an insulation layer, on the inner
`surface of the contact holes, and then filling the contact holes
`with a deposited metal such as an Al—Si alloy while heating
`the semiconductor substrate to a desired temperature of 500°
`C.
`to 550° C., as in Ono et al. paper (Korean Laid-open
`Patent Publication No. 90-15277 and European Patent
`Application No. 901041840 corresponding to Japanese
`Patent Application No. 01-061557 filed on Mar. 14, 1989.).
`According to the Yoda Dakashi et a1. and Ono et al.
`methods, an Al—Si film is deposited at a temperature of
`
`Page 12 of 23
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`Page 12 of 23
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`5,869,902
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`3
`to 550° C. The Al—Si film thus obtained has a
`500° C.
`grown-up large diameter of crystalline particles of about 10
`microns. Therefore,
`there is a high probability that
`the
`Al—Si film has a strong resistance against electron migra-
`tion but a weak resistance against stress migration. In
`addition, high resistant Si
`is crystallized at
`interfaces
`between crystalline particles of the Al—Si film. Thus, it is
`necessary to remove the Al—Si film at the areas other than
`the contact hole area and the metallization process become
`complicated. Additionally, since the Al—Si film is deposited
`at a high temperature, a void is formed or metal layer
`discontinuities occur. FIG. 2 illustrates a void formation lib
`when depositing a metal layer at a high temperature. In the
`same figure, the reference numerals indicate the same por-
`tion as in FIG. 1, except for metal layer 9b deposited at a
`high temperature and void 11b. Also, FIG. 3 illustrates a
`discontinuity 13 of a metal layer 9c formed in a contact hole,
`when depositing a metal layer at a high temperature. In the
`same figure, the reference numerals indicate the same por-
`tion as in FIG. 1, except for metal layer 9c deposited at a
`high temperature and the discontinuity 13.
`As an alternative to melting Al or Al alloy for filling
`contact holes, and in order to improve the metal step
`coverage, a multiple step metallization process is disclosed
`in US. Pat. No. 4,970,176 (Clarence J. Tracy et al.).
`According to this patent, a predetermined first thickness of
`a metal layer is deposited on a semiconductor wafer at a cold
`temperature. Then,
`the temperature is increased
`to-approximately 400° C. to 500° C., which allows the metal
`layer to reflow while depositing the remaining and relatively
`thin second thickness of the metal layer. The reflow of the
`metal layer takes place through grain growth, recrystalliza-
`tion and bulk diffusion.
`
`According to the Tracy et al. method, the step coverage of
`a contact hole (via hole) having a high‘ aspect ratio can be
`improved. However, there is high probability that a void lib
`as in FIG. 2 or a discontinuity 13 as in FIG. 3 forms in a
`metal layer, since the metal layer is deposited at a high
`temperature. Additionally, the aluminum or aluminum alloy
`cannot completely fill a contact hole having an aspect ratio
`greater than one and a diameter less than 1 am.
`Additionally, C. S. Park et al. (which includes the present
`inventors) have disclosed a method for forming a metal
`wiring layer through a contact hole having a high aspect
`ratio which comprises the Ste 5 of depositing an aluminum
`alloy to a thickness of 3000
`at a low temperature below
`100° C. and post-heating the deposited aluminum alloy at a
`temperature of 550° C. for 180 seconds.
`to thereby com-
`pletely fill up the contact hole with aluminum alloy, in Proc.,
`1991 VMIC Conference, June 11 and 12, pp. 326—328. This
`method is included in US. patent application Ser. No.
`07/585,218 entitled “A Method for Forming a Metal Layer
`in a Semiconductor Device,” which has now been aban-
`doned and a continuation-in—part
`thereof US. Pat. No.
`5,318,923.
`FIGS. 4 through 6 show a method for forming a metal
`layer according to the above invention. FIG. 4 illustrates a
`step for forming a first metal layer. A 0.8 ,um-sized contact
`hole 22 having a step formed thereon is formed in an
`insulating layer 25 coated on semiconductor substrate 10.
`Then, substrate 21 is put into a sputtering reaction chamber
`(not showu), in which a first metal layer 27 is formed by
`depositing a metal such as aluminum (Al) or Al alloy, at a
`temperature of 150° C. or less and under a predetermined
`degree of vacuum. First metal layer 27 thus obtained is
`comprised of small aluminum grains having a high surface
`free energy.
`
`v-
`
`10
`
`20
`
`30
`
`4O
`
`50
`
`60
`
`4
`FIG. 5 illustrates the method of filling contact hole 22.
`More particularly, after the semiconductor wafer thus
`obtained is moved into another sputter reaction chamber (not
`shown), Without breaking the vacuum, first metal layer 27 is
`heat-treated for at least two minutes at a temperature of 550°
`C., thereby filling up the contact hole 22 with the metal. At
`this time, the pressure in the reaction chamber is preferably
`as low as possible so that the aluminum atoms have a higher
`surface free energy. In this manner, the metal atoms can
`more easily migrate into the contact holes, thereby filling
`them. The reference numeral 27a designates a metal layer
`filling contact hole 22.
`a
`The heat treatment temperature range in the step shown
`FIG. 5 is between 80% of the melting point of the metal and
`the melting point of the metal, and will vary according to the
`particular aluminum alloy or aluminum employed.
`Since the metal layer is heat-treated at a temperature
`lower than aluminum’s melting point, the metal layer does
`not melt. For example, at 550° C., the Al atoms deposited by
`sputtering at a temperature below 150° C. migrate upon
`heat-treatment at a higher temperature, instead of melting.
`This migration increases when the surface area is uneven or
`grainy due to an increase in energy among the surface atoms
`which are not in full contact with surrounding atoms. Thus,
`the initially sputtered, grainy layer exhibits an increase in
`atomic migration upon heat-treatment.
`FIG. 6 illustrates a step for forming a second metal layer
`29. More particularly, second metal layer 29 is formed by
`depositing the remainder of the required total metal layer
`thickness at a temperature selected on the basis of the
`desired reliability of the semiconductor device, for example
`at a temperature below 350° C. This completes the formation
`of the total (composite) metal layer.
`According to the above method, the contact hole can be
`easily and fully filled with metal, by using the same sput-
`tering equipment used for
`the conventional deposition
`method and then annealing the deposited metal. Therefore,
`even a contact hole with a high aspect ratio can be com-
`pletely filled. However, when a void is formed in the contact
`hole or when the step coverage of the metal
`layer is
`inadequate,
`the contact hole cannot be filled up while
`maintaining such a semiconductor wafer with metal layer at
`a certain temperature and vacuum level. Further, although a
`secondary metal layer is subsequently formed on the semi—
`conductor wafer having a previously deposited primary
`metal layer, good step coverage of the contact hole cannot be
`assured, and the reliability of the manufactured semicon-
`ductor device is degraded due to this inadequate step cov-
`erage.
`For preventing a void formation and obtaining a good step
`coverage and a planarized surface of a wiring layer, S. 1. Lee
`(one of the present
`inventors) et al. have an invention
`entitled “Method for Manufacturing a Semiconductor
`Device,” and filed as US. Pat. No. 5,266,521 now pending
`in the USPTO, This invention relates to a method for
`forming a metal wiring layer through a contact hole in a
`semiconductor device, which comprises the steps of forming
`a first metal layer on a semiconductor substrate coated with
`an insulating layer having a contact hole formed thereon,
`heat-treating the first metal layer to completely fill up the
`contact hole with a metal of the first metal layer, forming a
`second metal layer on the first metal layer and then heat-
`treating the second metal layer to planarize a surface thereof.
`According to the invention described in the Lee et al.
`application, the above second metal layer is heat-treated in
`the same manner as the first metal layer, to thereby planarize
`
`Page 13 of 23
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`Page 13 of 23
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`5,869,902
`
`5
`the surface of the metal layer to thereby improve a subse-
`quent photolithography process before forming a metal
`wiring pattern. Additionally, a metal with no Si component
`and a metal with a Si component may be deposited to form
`a composite metal
`layer. When the temperature of the
`semiconductor substrate is lowered, a metal layer with no Si
`component absorbs Si atoms from the metal with the Si
`component. Therefore, Si precipitates are not formed on the
`surface of the semiconductor substrate after forming the
`wiring pattern. Although Si precipitate formation is
`prevented, when forming a composite metal layer according
`to the above invention, when a poor diffusion barrier layer
`formed on the inner surface of a contact hole exists, a fine
`junction spiking occurs, by which the junction is
`deteriorated, and which, over time, will increase leakage
`current.
`
`For preventing this fine junction spiking, Lee et al. further
`have an invention entitled “Semiconductor Device and
`Manufacturing Method thereof”, and filed‘as US. Pat.
`application Ser. No. 5,355,020 now pending in the USPTO.
`It is also presently known that, for improving the reli-
`ability of the semiconductor by preventing degradation of
`the shallow junction characteristics due to Al spiking, a
`barrier layer can be formed in the contact hole formed on the
`semiconductor wafer. For example,
`the formation of a
`titanium nitride film by a reactive sputtering method is
`disclosed in J. Vac. Sci. Technol., A4 (4), 1986, pp.
`1850—1854.
`In US. Pat. No. 4,897,709 (by Natsuki
`Yokoyama et al.), there is described a semiconductor device
`including a titanium nitride film sewing as a barrier layer
`which is formed in a contact hole for preventing a reaction
`between the metal wiring layer and the semiconductor
`substrate. The titanium nitride film can be formed by a low
`pressure CVD method implemented with a cold-type CVD
`apparatus. The resultant film has excellent characteristics
`with good step coverage for a considerably fine hole having
`a large aspect ratio. After forming the titanium nitride film,
`a wiring layer is formed by a sputtering method using an Al
`alloy.
`Additionally, in the above—mentioned Yoda Dakashi et al
`patent publication, there is disclosed a method for manu-
`facturing a semiconductor device which comprises the step
`of forming double barrier layers for preventing a reaction
`between the wiring layer and the semiconductor substrate or
`an insulation layer, on the inner surface of the contact hole.
`Additionally,
`in Japanese Patent Laid-open Publication
`No. 61-183942, there is described a method for forming a
`barrier layer which comprises the steps of forming a refrac-
`tory metal layer by depositing a metal such as Mo, W, Ti or
`Ta, forming a titanium nitride layer on the refractory metal
`layer, and heat-treating the metal layer and the titanium
`nitride layer to thereby form a refractory metal silicide layer
`at the inter—surface of the refractory metal layer and semi-
`conductor substrate by a reaction therebetween. Thus, the
`barrier characteristic is improved. The heat-treatment the
`diffusion barrier layer is performed by an annealing process
`under a nitrogen atmosphere at a temperature of 450° C. for
`about 30 minutes. When the barrier layer does not undergo
`the annealing process, a junction spiking occurs in a subse-
`quent sintering step afterAl sputtering or in sputtering Al or
`an Al alloy at a temperature above 450° C,, which is
`undesirable.
`
`Also, after forming the diffusion barrier layer, a semicon-
`ductor wafer should be transported into a sputtering appa-
`ratus for forming a metal wiring layer. Thus, the diffusion
`barrier layer is exposed to the atmosphere. Exposing the
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`diffusion barrier layer to the atmosphere or annealing pro-
`cess enables a quite small amount of atoms of the diffusion
`barrier layer to react with oxygen to form a very thin oxide
`layer on the surface portion of the diffusion barrier layer,
`which improves the diffusion barrier effect. This is called a
`“stufling effect.” On the oxide layer, the mobility of alumi-
`num atoms reduces and when depositing an Al-1% Si-0.5%
`Cu alloy to a thickness of about 6,000 A at a room
`temperature, the metal layer thus obtained has a grain size as
`small as 0.2 ,um. Thus, the step coverage of a sputtered Al is
`insuflicient.
`
`In the meantime, on a diffusion barrier layer which is not
`exposed to the atmosphere or the annealing process, alumi-
`num reacts with the diffusion barrier layer during a subse-
`quent heat-treating step at a high temperature or when
`depositing an aluminum film by sputtering at a high
`temperature, to thereby deteriorate the barrier effect of the
`diffusion barrier layer. Additionally, the surface of the Al
`metal
`layer becomes rugged and a surface reflectivity
`thereof becomes low, which lowers the efficiency of a
`subsequent photolithography process. Therefore, the anneal-
`ing process is essential.
`To improve wettabilities between the barrier metal and an
`Al wire, Hagita Masafumi suggested a method for forming
`a diffusion barrier layer comprising a step of implanting
`oxygen or silicon into the barrier metal after heat-treating
`TiN layer as a diffusion barrier layer (Japanese Patent
`Laid-Open Publication No.2-26052). Also, Dipankar Pra-
`manik et al. reported a grain size and intragrain roughness of
`aluminum films studied for Various underlayer (“Effect of
`Underlayer on Sputtered Aluminum Grain Structure and Its
`correlation with Step Coverage in Submicron Vias”, by
`Dipankar Pramanik and Vivek Jain, Jun. 12—13, 1990 VMIC
`Conference pp 332—334). According to Dipankar Pramanik
`et al., when at an initial stage of Al deposition, a large island
`is formed on the sidewalls, and excellent step coverage was
`obtained to thereby result a continuous Al film. From this, it
`can be noted that if the grain size on the sidewalls is large,
`a continuous metal film can be obtained and can easily
`migrate into a contact hole without discontinuity of a metal
`layer when heat-treating the metal layer according to the C,
`S. Park method. This is 'due to the increased wettability
`between the underlayer and the sputtered Al.
`The present inventors have found that providing a reactive
`spacer which has a good wettability with a sputtered Al on
`the sidewalls of a contact hole and therefore produces a large
`island at the initial sputtering stage (that is, large grain of the
`sputtered Al film), improves the step coverage of the sput-
`tered Al film and the refiow of the Al metal layer into the
`contact hole. On these bases, the present invention has been
`accomplished.
`SUMMARY OF THE INVENTION
`
`Accordingly, it is an object of the present invention to
`provide a semiconductor device including a reliable wiring
`layer which comprises a reactive spacer or layer formed on
`a side Wall of a contact hole, which can enhance the
`wettability of the Al sputtered film at an initial deposition
`stage to thereby prevent a void formation of a metal layer in
`the depositing step, and improves the reflow of the sputtered
`Al film to thereby prevent a discontinuity of a metal layer in
`a subsequent heat-treating step for filling the contact hole.
`Another object of the present invention is to provide a
`method for manufacturing a semiconductor device including
`a wiring layer as above.
`Briefly, according to the present invention, there is pro-
`vided a semiconductor device comprising a reactive spacer
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`5,869,902
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`7
`recessed portion, which
`formed on the sidewall of a
`improves step coverage of a conductive layer in a depositing
`step and enhances reflow of a material of the conductive
`layer in a step of reflowing of the material of the conductive
`layer by heat-treating the conductive layer, after forming the
`conductive layer.
`Additionally, the present invention provides a semicon-
`ductor device comprising a reactive layer formed on the
`inner surface a recessed portion, which improves step cov-
`erage of a conductive layer in a depositing step and enhances
`reflow of a material of the conductive layer in a step of
`reflowing of the material of the conductive layer by heat-
`treating the conductive layer, after forming the conductive
`layer.
`Examples of such a recessed portion are an opening such
`as a contact hole or a via and a groove.
`Also, the above object of the present invention may be
`accomplished by providing a semiconductor including a
`wiring layer comprising: a semiconductor substrate; an
`insulating layer having an opening formed on the semicon-
`ductor substrate, the opening exposing a portion of a surface
`of an underlying layer of the insulating layer; a reactive
`spacer formed on a side wall of the opening; and a first
`conductive layer formed on the insulating layer, on the
`reactive spacer and on the exposed surface portion of the
`underlying layer. Here, the opening is a contact hole which
`extends to the surface of the semiconductor substrate,
`thereby exposing a portion of the surface of the semicon-
`ductor substrate or a via which connects an upper conductive
`layer to a lower conductive layer in a multilevel intercon-
`nection and exposes a portion of the lower conductive layer
`underlying the insulating layer.
`the
`According to one aspect of the present invention,
`reactive spacer or layer is comprised of an element which
`lowers the melting point of a material of the first conductive
`layer. Any element may be used in the present invention so
`far as it lowers the melting point of the material of the first
`conductive layer. The elements used in the present invention
`include, for example, Ge, Mg, Sn, In, Pb, Zn etc. These
`elements maybe used either alone or in a mixture thereof.
`According to another aspect of the present invention, the
`reactive spacer or layer may be comprised of transition
`metals such as Ti, Mo, Ta, W etc or
`transition metal
`compounds such as TiN. These transition metals and tran-
`sition metal compounds may be used either alone or in a
`mixture thereof.
`
`Additionally, according to the present invention, there is
`provided a method for manufacturing a semiconductor
`device including a wiring layer, comprising the steps of:
`forming an insulating layer on a semiconductor substrate;
`providing the insulating layer with an opening exposing a
`portion of a surface of an underlying layer of the insulating
`layer; forming a reactive spacer on a side wall of the
`opening; and forming a first conductive layer on the insu-
`lating layer, on the reactive spacer and on the exposed
`surface portion of the underlying layer. The reactive spacer
`is formed by depositing a reactive material to form a reactive
`material layer on the insulating layer, on a sidewall of the
`opening and the exposed surface portion of the underlying
`layer and selectively removing the reactive material layer on
`the insulating layer and the exposed surface portion of the
`underlying layer by an etch-back process.
`Additionally, the present invention provides a method for
`manufacturing a semiconductor device including a wiring
`layer, comprising the steps of: forming an insulating layer on
`a semiconductor substrate; providing the insulating layer
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`with an opening exposing a portion of a surface of an
`underlying layer of the insulating layer; forming a reactive
`spacer on a sidewall of the opening; forming a first conduc-
`tive layer on the insulating layer, on the reactive spacer, and
`on the exposed surface portion of said underlying layer; and
`heat-treating the first conductive layer for an appropriate
`time to fill up the opening with the material of said first
`conductive layer, without breaking vacuum after forming the
`first conductive layer.
`invention provides a method for
`Further,
`the present
`manufacturing a s